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200 00$aAdvanced propulsion systems and technologies, today to 2020$b[electronic resource] /$fedited by Claudio Bruno, Antonio G. Accettura
210   $aReston, Va. $cAmerican Institute of Aeronautics and Astronautics$dc2008
215   $a1 online resource (506 p.)
225 1 $aProgress in astronautics and aeronautics ;$vv. 223
300   $a"Commissioned by the European Space Agency"--P. [4] of cover.
311   $a1-56347-929-X 
320   $aIncludes bibliographical references and index.
327   $aIntroduction -- Advanced solid rocket motors -- Advanced cryogenic engines -- Advanced LOX-HC engines for boosters and upper stages -- LOX-hydrocarbon engines in Russia -- Green propellants -- Green propellants in Russia -- Miniaturized propulsion -- Solar thermal propulsion for upper stages -- Electric-propulsion systems -- Superconductivity -- The case for nuclear propulsion : the Rubbia's engine -- VASIMR prefeasibility analysis -- Laser propulsion systems -- Mass accelerators : Maglev and Railguns -- Solar sails : propellantless propulsion for near- and medium-term deep-space missions -- In situ resource utilization.
410  0$aProgress in astronautics and aeronautics ;$vv. 223.
606   $aSpace vehicles$xPropulsion systems
606   $aPropulsion systems
608   $aElectronic books.
615  0$aSpace vehicles$xPropulsion systems.
615  0$aPropulsion systems.
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712 02$aAmerican Institute of Aeronautics and Astronautics.
712 02$aEuropean Space Agency.
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200 00$aOptical shop testing$b[electronic resource] /$fedited by Daniel Malacara
205   $a3rd ed.
210   $aHoboken, N.J. $cWiley-Interscience$dc2007
215   $a1 online resource (884 p.)
225 1 $aWiley series in pure and applied optics
300   $aDescription based upon print version of record.
311   $a0-471-48404-0 
320   $aIncludes bibliographical references and index.
327   $aOptical Shop Testing; Contents; Preface; Contributors; Chapter 1. Newton, Fizeau, and Haidinger Interferometers; 1.1. Introduction; 1.2. Newton Interferometer; 1.2.1. Source and Observer's Pupil Size Considerations; 1.2.2. Some Suitable Light Sources; 1.2.3. Materials for the Optical Flats; 1.2.4. Simple Procedure for Estimating Peak Error; 1.2.5. Measurement of Spherical Surfaces; 1.2.6. Measurement of Aspheric Surfaces; 1.2.7. Measurement of Flatness of Opaque Surfaces; 1.3. Fizeau Interferometer; 1.3.1. The Basic Fizeau Interferometer; 1.3.2. Coherence Requirements for the Light Source
327   $a1.3.3. Quality of Collimation Lens Required1.3.4. Liquid Reference Flats; 1.3.5. Fizeau Interferometer with Laser Source; 1.3.6. Multiple-Beam Fizeau Setup; 1.3.7. Testing Nearly Parallel Plates; 1.3.8. Testing the Inhomogeneity of Large Glass or Fused Quartz Samples; 1.3.9. Testing the Parallelism and Flatness of the Faces of Rods, Bars and Plates; 1.3.10. Testing Cube Corner and Right-Angle Prisms; 1.3.11. Fizeau Interferometer for Curved Surfaces; 1.3.12. Testing Concave and Convex Surfaces; 1.4. Haldinger Interferometer; 1.4.1. Applications of Haidinger Fringes
327   $a1.4.2. Use of Laser Source for Haidinger Interferometer1.4.3. Other Applications of Haidinger Fringes; 1.5. Absolute Testing of Flats; Chapter 2. Twyman-Green Interferometer; 2.1. Introduction; 2.2. Beam-Splitter; 2.2.1. Optical Path Difference Introduced by the Beam Splitter Plate; 2.2.2. Required Accuracy in the Beam Splitter Plate; 2.2.3. Polarizing Cube Beam Splitter; 2.2.4. Nonpolarizing Cube Beam Splitter; 2.3. Coherence Requirements; 2.3.1. Spatial Coherence; 2.3.2. Temporal Coherence; 2.4. Uses of a Twyman-Green Interferometer; 2.4.1. Testing of Prisms and Diffraction Rulings
327   $a2.4.2. Testing of Lenses2.4.3. Testing of Microscope Objectives; 2.5. Compensation of Intrinsic Aberrations in the Interferometer; 2.6. Unequal-Path Interferometer; 2.6.1. Some Special Designs; 2.6.2. Improving the Fringe Stability; 2.7. Open Path Interferometers; 2.7.1. Mach-Zehnder Interferometers; 2.7.2. Oblique Incidence Interferometers; 2.8. Variations from the Twyman-Green Configuration; 2.8.1. Multiple Image Interferometers; 2.8.2. Interferometers with Diffractive Beam Splitters; 2.8.3. Phase Conjugating Interferometer; 2.9. Twyman-Green Interferograms and their Analysis
327   $a2.9.1. Analysis of Interferograms of Arbitrary WavefrontsChapter 3. Common-Path Interferometers; 3.1. Introduction; 3.2. Burch's Interferometer Employing Two Matched Scatter Plates; 3.2.1. Fresnel Zone Plate Interferometer; 3.2.2. Burch and Fresnel Zone Plate Interferometers for Aspheric Surfaces; 3.2.3. Burch and Fresnel Zone Plate Interferometers for Phase Shifting; 3.3. Birefringent Beam Splitters; 3.3.1. Savart Polariscope; 3.3.2. Wollaston Prism; 3.3.3. Double-Focus Systems; 3.4. Lateral Shearing Interferometers; 3.4.1. Use of a Savart Polariscope; 3.4.2. Use of a Wollaston Prism
327   $a3.5. Double-Focus Interferometer
330   $aThe purpose of this third edition is to bring together in a single book descriptions of all tests carried out in the optical shop that are applicable to optical components and systems. This book is intended for the specialist as well as the non-specialist engaged in optical shop testing. There is currently a great deal of research being done in optical engineering. Making this new edition very timely.
410  0$aWiley series in pure and applied optics.
606   $aOptical measurements
606   $aInterferometry
606   $aInterferometers
608   $aElectronic books.
615  0$aOptical measurements.
615  0$aInterferometry.
615  0$aInterferometers.
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