InhaltsangabeChapter 1. Foundation of the aspheric optical polishing technology 1.1 Advantages and application of aspheric optics 1.2 The characteristics of manufacturing aspheric mirror 1.3 The manufacturing technology for ultra-smooth surface 1.4 The advanced aspheric optical polishing technology 1.5 The CCT based on elasticity theory 1.6 The key basic theory of CCT technology based on the multi-energy field References Chapter 2. The basic theory of aspheric optical lapping and polishing technology 2.1 The preston equation of optical-mechanical polishing technology and its application 2.2 The deterministic processing principle for aspheric 2.3 The molding theory of aspheric surface processing 2.4 The figuring theory of linear scanning mode on full-aperture 2.5 The polar scanning mode of surface figuring 2.6 The frequency domain analysis of forming 2.7 Maximum entropy principle of polishing References Appendix a: two-dimensional hermite series Appendix b: two-dimensional fouier series Appendix c: the dual-series model solution of dwell time Appendix d: the error analysis of the dual-series model solution for dwell time Chapter 3 CCOS technology based on small polishing pad 3.1 Review of CCOS technology based on small polishing pad 3.2 AOCMT optical aspherical mirror process machine tool 3.3 Modelling and analysis of removal function 3.4 Dwell time calculation and analysis in CCOS technology 3.5 Removal function modelling under the edge effect 3.6 Cause and modification method of optical surface small scale manufacturing error Reference Chapter 4 IBF technology 4.1 Outline of IBF technology 4.2 Basic principle of IBF for optical mirror 4.3 Analysis of removal function model in IBF 4.4 IBF system design and analysis 4.5 Microscale error evolution during IBF 4.6 The polishing experiment of IBF Reference Chapter 5 Magnetorheological Figuring(MRF) 5.1 Overview of MRF 5.2 Mechanism and Mathematical Model of MRF material removal 5.3 MRF machine tools 5.4 MR fluid and its performance 5.5 Optimization of MRF processing parameters 5.6 MRF optical surfacing technique and machining experiment 5.7 Magnetorheological Jet Polishing Reference Chapter 6 Evaluation of deterministic optical machining errors 6.1 Introduction 6.2 Usual evaluation method of optical machining errors 6.3 Analysis on distribution characteristics of optical machining errors 6.4 Scattering evaluation of optical machining errors 6.5 Evaluation of frequency band errors based on optical performance Reference Chapter 7 Measurement technology in manufacturing of large-middle optical surfaces 7.1 Introduction 7.2 Principles of coordinate measurement technology in manufacturing of large-middle optical surfaces 7.3 Interferometric null test in manufacturing of large-middle optical surfaces 7.4 Nonnull test in manufacturing of largemiddle optical surfaces 7.5 Phase retrieval technology 7.6 Subsurface quality assessment Chapter 8 Coordinate measuring technology of optical aspheric surface 8.1 State of the art of the Coordinate measuring technology of optical aspheric surface 8.2 Large aperture aspheric coordinate measuring technology 8.3 The swing arm measurement of large aspheric Reference Chapter 9 Subaperture stitching interferometry 9.1 Introduction 9.2 Fundamentals of subaperture stitching algorithm 9.3 Iterative algorithm for subaperture stitching 9.4 Method for subaperture lattice design 9.5 Subaperture stitching interferometer 9.6 Case study 9.7 Future development of subaperture stitching interferometry Appendix References Chapter 10 Phase retrieval in-situ testing of large-middle optical surfaces 10.1 Introduction to phase retrieval technology 10.2 Basic principle and algorithm for phase retrieval optical testing 10.3 PR testing of spherical wavefron

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