課程資訊
課程名稱
衍射光學與全像影像術
Holographic Imaging and Diffractive Optics 
開課學期
105-1 
授課對象
理學院  物理學研究所  
授課教師
駱遠 
課號
Phys8107 
課程識別碼
222 D3280 
班次
 
學分
全/半年
半年 
必/選修
選修 
上課時間
星期五7,8(14:20~16:20) 
上課地點
新物833 
備註
總人數上限:20人
外系人數限制:5人 
Ceiba 課程網頁
http://ceiba.ntu.edu.tw/1051Phys8107 
課程簡介影片
 
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課程概述

This course describes the nature of holographic and lithographically formed diffraction volume/thin gratings and necessary tools for their design and analysis. Course topics include a description of the interference and Fourier relations that determine the amplitude of diffracted fields, analysis of volume gratings, and properties of holographic recording materials, binary gratings, and analysis of applications of holography including bio-imaging and data storage, fiber Bragg gratings, and polarization control elements.
This class can complement the courses of Optics (光學導論) and Advanced Bio-Optical Microscopy (高等生物光學顯微術).
 

課程目標
本課程將介紹光學醫學影像技術,著重衍射光學與全像影像術的設計與理論,此課程會將光學導論延伸至高等生物光學顯微術的實際應用。上課期間,也將有部分光學影像實驗demo.
Outline:
1.Basic concepts
2.Introduction of terminology
3.Basic holographic recording process
4.Analysis of holographic recording based on spatial frequency analysis
5.Fourier analysis of holography
6.Image analysis of holography
7.Hologram recording requirements
8.Coupled wave analysis
9.Digital holography
10.Optical data storage
11.Volume holographic imaging
12.Other applications
 
課程要求
大學普物物理 
預期每週課後學習時數
 
Office Hours
 
參考書目
The book by Goodman is highly recommended and a book by Psaltis is a good review.

(1)Goodman, J.W. (2005). Introduction to Fourier Optics, (3rd ed.). McGraw Hill

(2)Coufal, H., Psaltis, D., and Sincerbox, G. (2000). Holographic Data Storage. Springer.
 
指定閱讀
待補 
評量方式
(僅供參考)
   
課程進度
週次
日期
單元主題
第1週
9/16  放假停課一天 
第2週
9/23  9/18Basic concepts and introduction of terminology(1) Overview of applications of holography(2) Differences between holographic and lens imaging(3) Absorption and phase modulation(4) Thin and thick gratings(5) Transmission and reflection gratings 
第3週
9/30  (1) Principles of holographic recording and reconstruction (2) Phase conjugation and time-reversed wave. (*HW1 uploaded with its deadline: 10/07/2016 ) 
第4週
10/07  Lab #1: digital holographic imaging: recording process and computational reconstruction procedure (臺大醫學院:聯教館,光電醫學研究中心1F,room #102) **HW#2 and HW#3 have been uploaded. 
第5週
10/14  Fourier analysis of gratings, including (1) review of Fresnel diffraction and Fraunhofer formulas, (2) diffraction patterns from apertures, and (3) Fourier analysis of absorption and phase gratings. 
第6週
10/21  (1) Fourier analysis of off-axis gratings, (2) difference between on-axis, and off-axis gratings, and (3) off-axis hologram reconstruction. (HW4 uploaded) 
第7週
10/28  Image analysis of holograms includes: (1) exact ray tracing, (2) paraxial ray tracing, and (3) aberration of holographic lenses. 
第8週
11/04  Ray-tracing coding for reference is uploaded (HW#5 is uploaded for example, 僅做參考不用繳交) 
第9週
11/11  Midterm 
第10週
11/18  Review questions for midterm quiz 
第11週
11/25  Guest lectures: (1) 3D holographic imaging by Dr. Chen Zhi (NUS/SMART Centre) (2) Whole embryo 3D formation using advanced microscopy 
第12週
12/02  Introduction of coherence: temporal/spatial coherence 
第13週
12/09  1. Visibility with polarization 2. Introduction of Kogelnik's theory 3. Bragg circle diagram (HW6 is posted online). 
第14週
12/16  (1) Introduction of Bragg condition & detuning parameter, (2) derivation of Kogelnik's theory, and (3) introduction of transmission/reflection volume holograms. (Kogelnik's paper uploaded) 
第15週
12/23  Principles of transmission and reflection volume holograms: (1) lossless dielectric, (2) lossy, and (3) absorption gratings. 
第16週
12/30  Projection presentation (I) 
第17週
1/06  Projection presentation (II) **上課時間(週五 中午12點至 2pm,地點:醫學院醫材影像所/聯教館 rm#102)