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1.

図書

図書
sponsored by the U.S. Army Research Office and The Ohio State University
出版情報: [Columbus, Ohio : Ohio State University, 1992]  256 p. ; 28 cm
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2.

図書

図書
International Textile Manufacturers Federation. Annual Conference ; International Textile Manufacturers Federation
出版情報: Zürich : International Textile Manufacturers Federation, 1992  59 p. ; 30 cm
シリーズ名: International textile manufacturing ; v. 15, 1992
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3.

図書

図書
International Conference & Exhibition for the Power Generation Industries
出版情報: Houston, TX : PennWell Conferences & Exhibitions, [1992]  6 v. ; 24 cm
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4.

図書

図書
Henri H. Arsenault, Yunlong Sheng
出版情報: Bellingham, Wash., USA : SPIE Optical Engineering Press, c1992  xi, 126 p. ; 26 cm
シリーズ名: Tutorial texts in optical engineering ; v. TT 8
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5.

図書

図書
Franklin T. Luk, chair/editor ; sponsored and published by SPIE--the International Society for Optical Engineering
出版情報: Bellingham, Wash., USA : SPIE, c1992  ix, 520 p. ; 28 cm
シリーズ名: Proceedings / SPIE -- the International Society for Optical Engineering ; v. 2027
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6.

図書

図書
editors, H. Pham and M.H. Hamza
出版情報: Anaheim, CA : IASTED : ACTA Press, [1992]  279 p. ; 28 cm
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7.

図書

図書
editor, M.H. Hamza
出版情報: Anaheim, CA : IASTED : ACTA Press, [1992]  379 p. ; 28 cm
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8.

図書

図書
AES International Conference ; Audio Engineering Society
出版情報: New York, N.Y., USA (60 E. 42nd St., New York 10165-0075) : Audio Engineering Society, c1992  359 p. ; 28 cm
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9.

図書

図書
KSP国際フォーラム ; KSP国際フォーラム実行委員会
出版情報: 川崎 : KSP国際フォーラム実行委員会事務局, [1992]  166p ; 30cm
シリーズ名: KSP国際フォーラム会議録 : 21世紀の世界と日本 / KSP国際フォーラム実行委員会 [編] ; 第2回
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10.

図書

図書
Daniel C. Harris
出版情報: Bellingham, Wash. : SPIE Optical Engineering Press, 1992  ix, 175 p. ; 26 cm
シリーズ名: Tutorial texts in optical engineering ; v. TT 10
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目次情報: 続きを見る
Preface
The Heat of the Night and the Dust of the Battlefield / 0.:
Electromagnetic spectrum and atmospheric transmission / 0.1:
Blackbody radiation / 0.2:
Transmission through rain, snow, fog and dust / 0.3:
References
Optical Properties of Infrared Windows / 1.:
A day in the life of a photon / 1.1:
Refraction and refractive index / 1.2:
Birefringence / 1.2.1:
Preference for cubic materials / 1.2.2:
Reproducibility of the refractive index / 1.2.3:
Reflection and transmission / 1.3:
Transmission of an absorbing window / 1.3.1:
Etalon effect / 1.3.2:
Optical constants: n and k / 1.4:
General behavior of absorption coefficient and refractive index / 1.5:
Transmission spectra of infrared materials / 1.6:
Measuring the absorption coefficient / 1.7:
Direct transmittance measurements / 1.7.1:
Laser calorimetry / 1.7.2:
Emissivity / 1.8:
Effect of temperature on absorption and emission / 1.9:
Free carrier absorption in semiconductors / 1.10:
What makes a window midwave or long wave? / 1.11:
"Two-color" materials / 1.12:
Optical Performance of Infrared Windows / 2.:
Resolution / 2.1:
Scatter / 2.2:
Modulation transfer function: a measure of imaging quality / 2.3:
Degradation of infrared sensing by a hot window / 2.4:
Emittance from a hot window / 2.4.1:
Temperature gradients in windows / 2.4.2:
Frequency doubling / 2.5:
Microwave transmission properties of infrared materials / 2.6:
Mechanical Properties / 3.:
Elastic constants / 3.1:
Measuring the strength of brittle materials / 3.2:
3-point and 4-point flexure tests / 3.2.1:
Equibiaxial disk flexure test / 3.2.2:
Ceramics fracture at pre-existing flaws / 3.3:
Stress concentration by cracks / 3.3.1:
Strain rate dependence of strength / 3.3.2:
Weibull statistics / 3.4:
The Weibull distribution / 3.4.1:
Safety factors / 3.4.2:
Strength scales with area (or volume) under stress / 3.5:
Strengths of optical ceramics / 3.6:
Strength is not an intrinsic property of a material / 3.6.1:
Temperature dependence of strength / 3.6.2:
Window and dome design / 3.7:
Designing a circular window / 3.7.1:
Designing a dome / 3.7.2:
Hardness and fracture toughness / 3.8:
Relation of strength to fracture toughness and grain size / 3.8.1:
Temperature dependence of hardness and fracture toughness / 3.8.2:
Thermal Properties / 4.:
Thermal expansion and heat capacity / 4.1:
Thermal conductivity / 4.2:
Thermal shock / 4.3:
Hasselman figures of merit / 4.3.1:
Klein figure of merit for minimum thickness dome / 4.3.2:
Mach-altitude limits for a dome / 4.3.3:
Aerodynamic domes / 4.4:
Thermal stability of window materials / 4.5:
Fabrication of Infrared Materials / 5.:
Classes of infrared materials / 5.1:
Glass-cermaics / 5.1.1:
Fabrication of polycrystalline materials by powder processing / 5.2:
Yttria: an example of dome fabrication from a powder / 5.2.1:
Methods of densifying ceramics: sintering, hot pressing and hot isostatic pressing / 5.2.2:
Annealing / 5.2.3:
Chemical vapor deposition / 5.3:
Zinc sulfide and zinc selenide / 5.3.1:
Silicon carbide and silicon nitride / 5.3.2:
Single-crystal materials / 5.4:
Gallium arsenide, gallium phosphide, germanium and silicon / 5.4.1:
Sapphire / 5.4.2:
Hot forging / 5.4.3:
Optical finishing / 5.5:
Scratch/dig specifications / 5.5.1:
Optical polishing / 5.5.2:
The effect of surface finish on mechanical strength / 5.6:
Polymer infrared windows / 5.7:
Optical Coatings / 6.:
Antireflection coatings / 6.1:
Moth eye surfaces / 6.1.1:
Interference fringes for measuring coating thickness / 6.1.2:
Adherence of coatings / 6.1.3:
Emittance from coatings / 6.1.4:
Rugate filters / 6.1.5:
Stress in coatings / 6.2:
Conductive coatings for electromagnetic shielding / 6.3:
Erosion and Erosion Protection / 7.:
Rainfall characteristics / 7.1:
The raindrop impact event / 7.2:
Raindrop damage threshold velocity / 7.3:
Threshold velocity for fracture or loss of mechanical strength / 7.3.1:
Threshold velocity for loss of optical transmission or contrast / 7.3.2:
Threshold velocity for loss of mass / 7.3.3:
Rain erosion test facilities / 7.4:
Whirling arm / 7.4.1:
Single-impact waterjet / 7.4.2:
Multiple-impact jet apparatus (MIJA) / 7.4.3:
Single-drop impact testing / 7.4.4:
Aerodynamic effects in rain erosion / 7.5:
Erosion by solid particles / 7.6:
Combined effects of sand and rain / 7.6.1:
Effect of angle of incidence on erosion / 7.7:
Waterdrop impact at inclined angles / 7.7.1:
Sand impact at inclined angles / 7.7.2:
Comparative erosion testing of materials / 7.7.3:
Protective coatings for erosion / 7.8:
Mechanisms of protection by coatings / 7.8.1:
Diamond-like carbon and germanium-carbon coatings / 7.8.2:
"Boron phosphide" and other phosphorus-based coatings / 7.8.3:
"REP" coating / 7.8.4:
Claddings / 7.8.5:
Diamond coatings / 7.8.6:
Proof Testing / 8.:
Case study: proof testing of zinc selenide / 8.1:
An example of an unsuccessful proof test / 8.1.1:
What is the stress intensity factor? / 8.2:
Slow crack growth / 8.3:
The theory of proof testing / 8.4:
How strength changes during a proof test / 8.4.1:
A theoretical example: proof testing of sapphire / 8.4.2:
Designing a proof test for the space shuttle window / 8.5:
Minimum time to failure after a proof test / 8.5.1:
Crack growth parameters for space shuttle window material / 8.5.2:
Proof test design / 8.5.3:
Fatigue / 8.6.:
Optical-Quality CVD Diamond / 9.:
What is diamond and how is it made? / 9.1:
Chemical vapor deposition of diamond / 9.1.1:
The two surfaces of CVD diamond / 9.1.2:
Mechanical and thermal properties of diamond / 9.2:
Hardness, toughness and elastic properties / 9.2.1:
Mechanical strength / 9.2.2:
Thermal expansion / 9.2.3:
Thermal conductivity and heat capacity / 9.2.4:
Commercial grades of CVD diamond / 9.2.5:
Optical properties of diamond / 9.3:
Absorption and scatter / 9.3.1:
Refractive index / 9.3.2:
Microwave properties of diamond / 9.3.3:
Diamond windows and domes / 9.4:
Polishing diamond / 9.4.1:
Mechanical and erosion performance / 9.4.2:
Oxidation of diamond / 9.4.3:
Prospects / 9.4.4:
Physical Constants and Conversion Factors / Appendix A:
Suppliers of Infrared Materials and Sources of Information / Appendix B:
Optical Properties of Infrared Materials / Appendix C:
Refractive index, absorption coefficient, and dn/dT / C.1:
Dispersion equations for refractive index / C.2:
Absorption coefficients of selected materials calculated by OPTIMATR / C.3:
Change of refractive index with isotropic pressure / C.4:
Definitions from Radiometry / Appendix D:
Elastic Constants / Appendix E:
The Weibull Distribution / Appendix F:
Weibull probability distribution / F.1:
Effective volume or area / F.2:
Weibull equations for different kinds of test specimens / F.3:
Relative strengths of different kinds of test specimens / F.4:
Weibull scaling by area instead of volume / F.5:
Thermal Properties of Selected Materials / Appendix G:
Index
Preface
The Heat of the Night and the Dust of the Battlefield / 0.:
Electromagnetic spectrum and atmospheric transmission / 0.1:
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