Optical Metrology Third Edition ;"T,3JQPn6 �:.J]s<J(F Kjell J. G˚asvik
�|w�)S
&�+ Spectra Vision AS, Trondheim, Norway
|�(��Q� !$ 
�_��W�� �+ k'b'A�y�(< Preface to the Third Edition xi
-q6d&D'B+� 1Basics 1
�J~=tR1�k 1.1 Introduction 1
16�G�p n�b 1.2 Wave Motion. The Electromagnetic Spectrum 1
�9&VfbrBM 1.3 The Plane Wave. Light Rays 3
^PrG�5|,�s 1.4 Phase Difference 4
Y�VT\@+�C' 1.5 Complex Notation. Complex Amplitude 5
p*l]I�*x'< 1.6 Oblique Incidence of A Plane Wave 5
�0n���('�F 1.7 The Spherical Wave 7
PZB_6!}2[F 1.8 The Intensity 8
uu`G<��n�� 1.9 Geometrical Optics 8
��lAZ�n0EU 1.10 The Simple Convex (Positive) Lens 10
cE SS�SH!m 1.11 A Plane-Wave Set-Up 11
lQ��!)0F�� 2 Gaussian Optics 15
�azT@�S=, 2.1 Introduction 15
�ZBcT�@hxm 2.2 Refraction at a Spherical Surface 15
x=�jS=�3$8 2.2.1 Examples 19
3�g��''�j7 2.3 The General Image-Forming System 19
6�O9?":�3; 2.4 The Image-Formation Process 21
>||��=�#�; 2.5 Reflection at a Spherical Surface 23
uL1$�y��f' 2.6 Aspheric Lenses 25
eA�BLBs�x� 2.7 Stops and Apertures 26
i<>zN^z�n� 2.8 Lens Aberrations. Computer Lens Design 28
��1,pg7L8H 2.9 Imaging and The Lens Formula 29
L,PD�4H"�8 2.10 Standard Optical Systems 30
$�E�Ulh��^ 2.10.1 Afocal Systems. The Telescope 30
p�jaDt��Nb 2.10.2 The Simple Magnifier 32
)�HPe}(ypt 2.10.3 The Microscope 34
!W?6,�i�-] 3 Interference 37
!h�S~\+E�� 3.1 Introduction 37
R3\o�LT�4� 3.2 General Description 37
�_�A�5�.�� 3.3 Coherence 38
k���nt��M� 3.4 Interference between two Plane Waves 41
�<-avC/M$d 3.4.1 Laser Doppler Velocimetry (LDV) 45
�.�e|�VW�) 3.5 Interference between other Waves 46
"1X@t'H3�8 3.6 Interferometry 49
�v$_YZm{!< 3.6.1 Wavefront Division 50
�z�&@O\>Q 3.6.2 Amplitude Division 51
hEr�O.ad1o 3.6.3 The Dual-Frequency Michelson Interferometer 54
-Uu65m~:{k 3.6.4 Heterodyne (Homodyne) Detection 55
�Qe,a�Ih�� 3.7 Spatial and Temporal Coherence 56
�W2� p�&LP 3.8 Optical Coherence Tomography 61
yWk�g���4� 4 Diffraction 67
Cg��4�l*"_ 4.1 Introduction 67
!T�3�b�]0z 4.2 Diffraction from a Single Slit 67
//W7$�DYEG 4.3 Diffraction from a Grating 70
L28DBj�E)A 4.3.1 The Grating Equation. Amplitude Transmittance 70
�i<�ug("/ 4.3.2 The Spatial Frequency Spectrum 73
[<H�'Js�Jl 4.4 Fourier Optics 75
!�ca����Y� 4.5 Optical Filtering 76
CpG]g>]L&[ 4.5.1 Practical Filtering Set-Ups 78
<�1xs
ya[e 4.6 Physical Optics Description
/Q*o6G�ys0 of Image Formation 81
gdKn!; ,w# 4.6.1 The Coherent Transfer Function 83
r'5�~�4'o$ 4.6.2 The Incoherent Transfer Function 85
+#Q\;;�FNP 4.6.3 The Depth of Focus 88
�b!hs|emo; 4.7 The Phase-Modulated Sinusoidal Grating 89
R3,�O;9i�� 5 Light Sources and Detectors 99
.W/�#$s|X\ 5.1 Introduction 99
[�(65^�Zl` 5.2 Radiometry. Photometry 99
�R�z\:)�<G 5.2.1 Lambertian Surface 102
D� Xjw"�^x 5.2.2 Blackbody Radiator 103
�0%f�}w0]: 5.2.3 Examples 105
YB&b_On,f� 5.3 Incoherent Light Sources 108
|ME��u"pY) 5.4 Coherent Light Sources 109
gZ� �b�+�m 5.4.1 Stimulated Emission 109
Z'F=Xw6;b� 5.4.2 Gas Lasers 112
P
g{/tM��Y 5.4.3 Liquid Lasers 114
qY^�@^)�b[ 5.4.4 Semiconductor Diode Lasers. Light Emitting Diodes 114
C�� ����7e 5.4.5 Solid-State Lasers 117
<!m'xO�D� 5.4.6 Other Lasers 119
:1/�K$A)^{ .
�!Ic{lB� � .
k.�MA�X8�� .
