衍射計(jì)算與數(shù)字全息

定　價(jià)：￥148.00

作　者：	李俊昌，吳艷梅編
出版社：	科學(xué)出版社
叢編項(xiàng)：	光學(xué)與光子學(xué)叢書(shū)
標(biāo)　簽：	暫缺

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ISBN：	9787030490919	出版時(shí)間：	2016-08-01	包裝：	精裝
開(kāi)本：	16開(kāi)	頁(yè)數(shù)：	664	字?jǐn)?shù)：

內(nèi)容簡(jiǎn)介

　　在激光應(yīng)用研究領(lǐng)域，標(biāo)量衍射理論能夠解決大量實(shí)際問(wèn)題。然而，衍射計(jì)算十分繁雜，國(guó)內(nèi)外研究的專(zhuān)著甚少，衍射計(jì)算通常成為大學(xué)生、研究生及科研人員遇到的難題。隨著計(jì)算機(jī)及CCD技術(shù)的進(jìn)步，基于衍射計(jì)算理論及計(jì)算機(jī)技術(shù)，數(shù)字全息逐漸形成一項(xiàng)具有重要前景的新興技術(shù)，國(guó)內(nèi)尚無(wú)一部專(zhuān)著闡述。《光學(xué)與光子學(xué)叢書(shū)：衍射計(jì)算與數(shù)字全息（下冊(cè) 英文版附光盤(pán)）》基于作者近30年在該領(lǐng)域的研究及國(guó)內(nèi)外的研究成果，除系統(tǒng)總結(jié)經(jīng)典衍射積分的數(shù)值計(jì)算方法外，將對(duì)空間曲面衍射場(chǎng)的數(shù)值計(jì)算進(jìn)行專(zhuān)門(mén)研究，并且，將以數(shù)字全息為衍射計(jì)算理論的應(yīng)用載體，較詳細(xì)地對(duì)數(shù)字全息涉及的理論、技術(shù)及在全息干涉計(jì)量中的應(yīng)用進(jìn)行介紹。

作者簡(jiǎn)介

　　李俊昌，Li Junchang，male，born in Kunming，Yunnan province， China on September 1 8th，1945，a professor frOm the College of Science，Kunming University of Science and Technology．He graduated from the Department of Physics．Yunnan University in 1967．1n the research field of Laser application．he has carried out scientific coopemtion with Institut National des Sciences Appliqu~e de Lyon，Ecole Centrale de Lyon，Ecole Nationale Superieure des Arts et M6ties de Paris and University du Maine and directed Ph．D students in China and France since 1984．吳艷梅，Wu Yanmei，female，born in Loudi，Hunan province， an associate professor．She graduated from Kunming University of Science and Technology，and obtained her Ph．D degree．In recent years，she has published fody― five papers，and won five teaching awards at the national Ievel．

圖書(shū)目錄

Introduction
Chapter 6 Reconstructing Wavefronts Propagated through an Optical System
6．1 General Discussion of Wavefront Reconstruction
6．1．1 CCD Detection Information Research Based on the Abbe Imaging Theory
6．1．2 Impulse Response of the Process
6．2 Digital Holography with a Zoom
6．2．1 Principle of the Zoom
6．2．2 Study of the Zoom
6．2．3 Design of the Zoom
6．3 Reconstructing an Image by Collins' Formula
6．3．1 Reconstruction Algorithm
6．3．2 Adjustable-magnification Reconstruction after Propagation across an Optical System
6．4 Using the Classical Diffraction Formula to Reconstruct the Wavefront after Propagation across an Optical System
6．4．1 Use of the Rigorous Diffraction Formula
6．4．2 Reconstruction of the Object Wave in the Object and Image Spaces
6．4．3 Digital Holographic Measurement of Matrix Elements in Optical System
References
Chapter 7 Basic Principles and Common Techniques of Holographic Interferometry
7．1 Single Exposure Method or Real-time Hologram Interferometry
7．1．1 Basic Principle of Single Exposure Method
7．1．2 Example of Real Time Holographic Interferometry
7．1．3 The Application of Special Carrier Phase-shifting in Real Time Holographic Testing
7．2 Double Exposure Method
7．2．1 Basic Principles of Double Exposure Method
7．2．2 Examples of Object Displacement Measurement and One Dimensional Measurement of Object Displacement
7．2．3 Testing of Three Dimensional Displacement Field with Double Exposure Method
7．3 Time Average Method
7．3．1 Basic Principle of Time Average Method
7．3．2 Example of Time Average Measurement
References
Chapter 8 Application of Digital Holography in Optical Testing
8．1 Creating Digital Holographic Interferogram and Its Phase Unwrapping
8．1．1 Creating Digital Holographic Interferogram and Its Representation
8．1．2 Phase Unwrapping of Interferogram
8．2 Common Techniques in Digital Holographic Testing
8．2．1 Digital Holographic Testing for Three Dimensional Profilometry
8．2．2 Digital Holographic Testing of Micro Deformation of Object
8．2．3 Time Average Method Digital Holography Vibration Analysis
8．2．4 Three-dimensional Particle Field Detection
8．3 Digital Holography Testing with Physical Optical Transformation System
8．3．1 General Discussion of Digital Holography System on Image Plane
8．3．2 Micro Digital Holography Testing of Tiny Object
8．3．3 Digital Holography Testing Example of Large-size Object
8．4 The Special Technology of Digital Holographic Interferometry
8．4．1 Digital Holographic Detecting Technology of Transient Process of Femtosecond Laser
8．4．2 Common Path Coaxial Macro-digital Holography Detection
8．4．3 Digital Holography Microscopy of Low Coherent LED Illuminating．
8．5 Digital Holography CT
8．5．1 Radon Transformation Introduction
8．5．2 Digital Holography CT Principle
8．5．3 The Detection Simulation of Digital Holographic VT
8．5．4 Application Example of Microscopy Digital Holography CT
……
References