| zhuljuan |
2014-02-21 18:01 |
MIT 光學(xué)
MIT 光學(xué) PPT (PDF版)23次課 下附目錄 Q_aqX(ig��
1 Introduction; brief history of optics; absorption, refraction; laws of reflection and refraction P�$18Xno�{
2 Laws of reflection and refraction; prisms; dispersion; paraboloidal reflector ��TcD�[Teu
3 Perfect focusing; paraboloidal reflector; ellipsoidal refractor; introduction to imaging; perfect on-axis imaging using aspheric lenses; imperfect imaging using spherical surfaces; paraxial approximation; ray transfer matrices �^'�&i�Y�V
4 Sign conventions; thin lens; real and virtual images zD2.Q%`I�M
5 Imaging at finite distances with thin lenses; thick lenses; the human eye; image formation by a composite lens 0^9:��KZ.!
6 Aperture stop; entrance and exit pupils; numerical aperture (NA); field stop; entrance and exit windows; field of view (FoV) b>QM~mq3^I
7 Ray tracing with mirrors; basic optical systems: single lens magnifier, eyepiece, microscope 'sRg4?P�T�
8 Basic optical systems (cont.): telescope; chromatic aberration; geometrical aberrations: spherical, coma K��r�/h`RM
9 Geometrical aberrations (cont.): astigmatism, field curvature, distortion; optical design demo; GRadient INdex (GRIN) optics: quadratic and axial profile; introduction to the Hamiltonian formulation C~{NKMeC/m
11 Hamiltonian formulation of ray tracing; analogies between Hamiltonian optics and Hamiltonian mechanics; introduction to waves 5,�
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12 1D wave equation; complex (phasor) representation; 3D waves: plane, spherical _7�lt(f[S
13 3D waves: plane, spherical; dispersive waves; group velocity; spatial frequencies; introduction to electromagnetics; Maxwell's equations; derivation of the wave equation for light Wk�`�bb!P_
14 Maxwell's equations (cont.); polarization justification of the refractive index; electromagnetic energy flux and Poynting's vector; irradiance (intensity) %�e
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15 Interference; Michelson and Mach-Zehnder interferometers; Huygens principle; Young interferometer; Fresnel diffraction C�[xJ�U�6z
16 Gratings: amplitude, phase, sinusoidal, binary m\/,c�c@,
17 Fraunhofer diffraction; review of Fourier transforms and theorems jQ_dw\�
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18 Spatial filtering; the transfer function of Fresnel propagation; Fourier transforming properties of lenses 1�xO!w�+J#
19 4F system (telescope with finite conjugates) as a cascade of Fourier transforms; binary amplitude and phase pupil masks; Point Spread Function (PSF) f4'El2>-86
20 Shift invariance; Amplitude Transfer Function (ATF); lateral and angular magnification in the 4F system; relationship between NA, PSF, and ATF; sampling and the Space Bandwidth Product (SBP); advanced spatial filtering: pupil engineering, phase contrast imaging; Talbot effect �K
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22 Temporal and spatial coherence; spatially incoherent imaging; Optical Transfer Function (OTF) and Modulation Transfer Function (MTF); comparison of coherent and incoherent imaging %�9T~8L
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23 Imaging with a single lens; resolution @%O�Py|=,{
25 Resolution (cont.); defocused optical systems jj!N39f ��
26 Depth of focus and depth of field; deconvolution and Tikhonov regularization; polarization; wave plates; effects of polarization on high-NA optical systems
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