Principles of physical optics:
Gespeichert in:
| 1. Verfasser: | |
|---|---|
| Format: | Buch |
| Sprache: | English |
| Veröffentlicht: |
Hoboken, N.J.
Wiley
2008
|
| Schlagworte: | |
| Online-Zugang: | Inhaltsverzeichnis |
| Beschreibung: | XIV, 492 S. Ill., graph. Darst. |
| ISBN: | 0470122129 9780470122129 |
Internformat
MARC
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| 100 | 1 | |a Bennett, Charles A. |e Verfasser |4 aut | |
| 245 | 1 | 0 | |a Principles of physical optics |c C. A. Bennett |
| 264 | 1 | |a Hoboken, N.J. |b Wiley |c 2008 | |
| 300 | |a XIV, 492 S. |b Ill., graph. Darst. | ||
| 336 | |b txt |2 rdacontent | ||
| 337 | |b n |2 rdamedia | ||
| 338 | |b nc |2 rdacarrier | ||
| 650 | 4 | |a Optique | |
| 650 | 4 | |a Optics | |
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Datensatz im Suchindex
| _version_ | 1804137117695082496 |
|---|---|
| adam_text | CONTENTS
Preface v
1
The Physics of Waves
1
1.1
Introduction
1
1.2
One-Dimensional Wave Equation
2
1.2.1
Transverse Traveling Waves On A String
3
1.3
General Solutions to the 1-D Wave Equation
5
1.4
Harmonic Traveling Waves
8
1.5
The Principle of Superposition
11
1.5.1
Periodic Traveling Waves
11
1.5.2
Linear Independence
12
1.6
Complex Numbers and the Complex Representation
12
1.6.1
Complex Algebra
13
1.6.2
The Complex Representation of Harmonic Waves
16
1.7
The Three-Dimensional Wave Equation
17
1.7.1
Three-Dimensional Plane Waves
19
1.7.2
Spherical Waves
20
2
Electromagnetic Waves and Photons
25
2.1
Introduction
25
2.2
Electromagnetism
26
ix
X
CONTENTS
2.3
Electromagnetic
Wave Equations
32
2.3.1
Transverse Electromagnetic Waves
34
2.3.2
Energy Flow and the Poynting Vector
38
2.3.3
Irradiance
39
2.4
Photons
42
2.4.1
Single-Photon Interference
47
2.5
The Electromagnetic Spectrum
48
Appendix: Maxwell s Equations in Differential Form
53
3
Reflection and Refraction
59
3.1
Introduction
59
3.2
Overview of Reflection and Refraction
60
3.2.1
Fermat s Principle of Least Time
63
3.3
Maxwell s Equations at an Interface
66
3.3.1
Boundary Conditions
66
3.3.2
Electromagnetic Waves at an Interface
67
3.4
The Fresnel Equations
69
3.4.1
Incident Wave Polarized Normal to the Plane of Incidence
70
3.4.2
Incident Wave Polarized Parallel to the Plane of Incidence
72
3.5
Interpretation of the Fresnel Equations
76
3.5.1
Normal Incidence
76
3.5.2
Brewster s Angle
76
3.5.3
Total Internal Reflection
78
3.5.4
Plots of the Fresnel Equations vs. Incident Angle
81
3.5.5
Phase Changes on Reflection
83
3.6
Reflectivity and Transmissivity
87
3.6.1
Plots of Reflectivity and Transmissivity vs. Incident Angle
90
3.6.2
The Evanescent Wave
92
3.7
*Dispersion
95
3.7.1
Dispersion in Dielectric Media
95
3.7.2
Dispersion in Conducting Media
104
3.8
Scattering
110
3.8.
1 Atmospheric Scattering
110
3.8.2
Optical Materials
115
4
Geometric Optics
119
4.1
Introduction
120
4.2
Reflection and Refraction at Aspheric Surfaces
120
4.3
Reflection and Refraction at a Spherical Surface
125
4.3.1
Spherical Reflecting Surfaces
125
4.3.2
Spherical Refracting Surfaces
128
CONTENTS
XI
4.3.3
Sign
Conventions and Ray
Diagrams
131
4.4
Lens Combinations
136
4.4.1
Thin-Lenses in Close Combination
137
4.5
*Principal Points and Effective Focal Lengths
138
4.6
Aberrations
143
4.6.1
Chromatic Aberration
143
4.6.2
Spherical Aberration
146
4.6.3
Astigmatism and Coma
147
4.6.4
Field Curvature
147
4.6.5
Diffraction
148
4.7
Optical Instruments
148
4.7.1
The Camera
148
4.7.2
The Eye
150
4.7.3
The Magnifying Glass
151
4.7.4
The Compound Microscope
152
4.7.5
The Telescope
153
4.7.6
The Exit Pupil
154
4.8
*Radiomerry
156
4.8.1
Extended Sources
159
4.8.2
Radiometry
of
Blackbody
Sources
161
4.8.3
Rayleigh-Jeans Theory and the Ultraviolet Catastrophe
163
4.8.4
Planck s Quantum Theory of
Blackbody
Radiation
165
4.9
Optical Fibers
169
4.10
Thick Lenses
174
4.10.1
*Principal Points and Effective Focal Lengths of Thick Lenses
176
4.11
*Introduction to Matrix Methods in Paraxial Geometrical Optics
180
4.11.1
The Translation Matrix
180
4.11.2
The Refraction Matrix
182
4.11.3
The Reflection Matrix
184
4.11.4
The Ray Transfer Matrix
185
4.11.5
Location of Cardinal Points for an Optical System
189
Appendix: Calculation of the Jeans Number
197
Superposition and interference
199
5.1
Introduction
200
5.2
Superposition of Harmonic Waves
200
5.3
Interference Between Two Monochromatic Electromagnetic Waves
201
5.3.1
Linear Power Detection
202
5.3.2
Interference Between Beams with the Same Frequency
203
5.3.3
Thin-Film Interference
206
5.3.4
Quasi-Monochromatic Sources
210
5.3.5
Fringe Geometry
211
XII CONTENTS
5.3.6
Interference Between Beams with Different Frequencies
212
5.4
Fourier Analysis
218
5.4.1
Fourier Transforms
218
5.4.2
Position Space, k-Space Domain
219
5.4.3
Frequency-Time Domain
223
5.5
Properties of Fourier Transforms
224
5.5.1
Symmetry Properties
224
5.5.2
Linearity
225
5.5.3
Transform of a Transform
225
5.6
Wavepackets
226
5.7
Group and Phase Velocity
232
5.8
Interferometry
235
5.8.1
*Energy Conservation and Complementary Fringe Patterns
240
5.9
Single-Photon Interference
243
5.10
Multiple-Beam Interference
244
5.10.1
The Scanning Fabry-Perot Interferometer
247
5.11
Interference in Multilayer Films
251
5.11.1
Antireflection Films
255
5.11.2
High-Reflectance Films
257
5.12
Coherence
259
5.12.1
Temporal Coherence
260
5.12.2
Spatial Coherence
261
5.12.3
Michelson s Stellar Interferometer
264
5.12.4
Irradiance
Interferometry
265
5.12.5
Telescope Arrays
266
Appendix: Fourier Series
269
281
282
282
284
285
286
291
293
295
297
298
299
301
308
6.3.10
Apodization
311
6
Diffraction
6.1
Introduction
6.2
Huygens Principle
6.2.1
Babinet s Principle
6.3 Fraunhofer
Diffraction
6.3.1
Single Slit
6.3.2
Rectangular Aperture
6.3.3
Circular Aperture
6.3.4
Optical Resolution
6.3.5
More on Stellar
Interferometry
6.3.6
Double Slit
6.3.7
N
Slits: The Diffraction Grating
6.3.8
The Diffraction Grating
6.3.9
Fraunhofer
Diffraction as a Fourier Transform
CONTENTS
ХІІІ
6.4 Fresnel
Diffraction
313
6.4.1 Fresnel
Zones
315
6.4.2
Holography
325
6.4.3
Numerical Analysis of Fresnel Diffraction with Circular Symmetry
327
6.4.4
Fresnel Diffraction from Apertures with Cartesian Symmetry
329
6.5
Introduction to Quantum Electrodynamics
338
6.5.1
Feynman s Interpretation
341
7
Lasers
345
7.1
Introduction
345
7.2
Energy Levels in Atoms, Molecules, and Solids
346
7.2.1
Atomic Energy Levels
346
7.2.2
Molecular Energy Levels
350
7.2.3
Solid-state Energy Bands
352
7.2.4
Semiconductor Devices
354
7.3
Stimulated Emission and Light Amplification
357
7.4
Laser Systems
361
7.4.1
Atomic Gas Lasers
363
7.4.2
Molecular Gas Lasers
364
7.4.3
Solid-State Lasers
367
7.4.4
Other Laser Systems
369
7.5
Longitudinal Cavity Modes
370
7.6
Frequency Stability
371
7.7
Introduction to Gaussian Beams
372
7.7.1
Overview of Gaussian Beam Properties
372
7.8
Derivation of Gaussian Beam Properties
375
7.8.1
Approximate Solutions to the Wave Equation
377
7.8.2
Paraxial Spherical Gaussian Beams
378
7.8.3
Gaussian Beam Focusing
380
7.8.4
Matrix Methods and the ABCD Law
384
7.9
Laser Cavities
385
7.9.1
Laser Cavity with Equal Mirror Curvatures
386
7.9.2
Laser Cavity with Unequal Mirror Curvatures
388
7.9.3
Stable Resonators
390
7.9.4
Traveling Wave Resonators
394
7.9.5
Unstable Resonators
394
7.9.6
Transverse Cavity Modes
395
8
Optical Imaging
399
8.1
Introduction
400
8.2
Abbe Theory of Image Formation
400
XIV CONTENTS
8.2.1 Phase
Contrast
Microscope
405
8.3
The Point
Spread Function
407
8.3.1
Coherent vs. Incoherent Images
407
8.3.2
Speckle
412
8.4
Resolving Power of Optical Instruments
413
8.5
Image Recording
415
8.5.1
Photographic Film
416
8.5.2
Digital Detector Arrays
417
8.6
Contrast Transfer Function
420
8.7
Spatial Filtering
422
8.8
Adaptive Optics
425
9
Polarization and Nonlinear Optics
431
9.1
Introduction
432
9.2
Linear Polarization
432
9.2.1
Linear Polarizers
433
9.2.2
Linear Polarizer Design
436
9.3
Birefringence
440
9.4
Circular and Elliptical Polarization
443
9.4.1
Wave Plates and Circular Polarizers
445
9.5
Jones Vectors and Matrices
449
9.5.1
Biréfringent
Colors
456
9.6
The Electro-optic Effect
458
9.6.1
Pockels Cells
459
9.6.2
Kerr Cells
461
9.7
Optical Activity
462
9.8
Faraday Rotation
463
9.9
Acousto-optic Effect
465
9.10
Nonlinear Optics
469
9.11
Harmonic Generation
471
9.11.1
Phase Conjugation Reflection by Degenerate Four-Wave Mixing
476
9.12
Frequency Mixing
478
References 4g3
Index
485
|
| adam_txt |
CONTENTS
Preface v
1
The Physics of Waves
1
1.1
Introduction
1
1.2
One-Dimensional Wave Equation
2
1.2.1
Transverse Traveling Waves On A String
3
1.3
General Solutions to the 1-D Wave Equation
5
1.4
Harmonic Traveling Waves
8
1.5
The Principle of Superposition
11
1.5.1
Periodic Traveling Waves
11
1.5.2
Linear Independence
12
1.6
Complex Numbers and the Complex Representation
12
1.6.1
Complex Algebra
13
1.6.2
The Complex Representation of Harmonic Waves
16
1.7
The Three-Dimensional Wave Equation
17
1.7.1
Three-Dimensional Plane Waves
19
1.7.2
Spherical Waves
20
2
Electromagnetic Waves and Photons
25
2.1
Introduction
25
2.2
Electromagnetism
26
ix
X
CONTENTS
2.3
Electromagnetic
Wave Equations
32
2.3.1
Transverse Electromagnetic Waves
34
2.3.2
Energy Flow and the Poynting Vector
38
2.3.3
Irradiance
39
2.4
Photons
42
2.4.1
Single-Photon Interference
47
2.5
The Electromagnetic Spectrum
48
Appendix: Maxwell's Equations in Differential Form
53
3
Reflection and Refraction
59
3.1
Introduction
59
3.2
Overview of Reflection and Refraction
60
3.2.1
Fermat's Principle of Least Time
63
3.3
Maxwell's Equations at an Interface
66
3.3.1
Boundary Conditions
66
3.3.2
Electromagnetic Waves at an Interface
67
3.4
The Fresnel Equations
69
3.4.1
Incident Wave Polarized Normal to the Plane of Incidence
70
3.4.2
Incident Wave Polarized Parallel to the Plane of Incidence
72
3.5
Interpretation of the Fresnel Equations
76
3.5.1
Normal Incidence
76
3.5.2
Brewster's Angle
76
3.5.3
Total Internal Reflection
78
3.5.4
Plots of the Fresnel Equations vs. Incident Angle
81
3.5.5
Phase Changes on Reflection
83
3.6
Reflectivity and Transmissivity
87
3.6.1
Plots of Reflectivity and Transmissivity vs. Incident Angle
90
3.6.2
The Evanescent Wave
92
3.7
*Dispersion
95
3.7.1
Dispersion in Dielectric Media
95
3.7.2
Dispersion in Conducting Media
104
3.8
Scattering
110
3.8.
1 Atmospheric Scattering
110
3.8.2
Optical Materials
115
4
Geometric Optics
119
4.1
Introduction
120
4.2
Reflection and Refraction at Aspheric Surfaces
120
4.3
Reflection and Refraction at a Spherical Surface
125
4.3.1
Spherical Reflecting Surfaces
125
4.3.2
Spherical Refracting Surfaces
128
CONTENTS
XI
4.3.3
Sign
Conventions and Ray
Diagrams
131
4.4
Lens Combinations
136
4.4.1
Thin-Lenses in Close Combination
137
4.5
*Principal Points and Effective Focal Lengths
138
4.6
Aberrations
143
4.6.1
Chromatic Aberration
143
4.6.2
Spherical Aberration
146
4.6.3
Astigmatism and Coma
147
4.6.4
Field Curvature
147
4.6.5
Diffraction
148
4.7
Optical Instruments
148
4.7.1
The Camera
148
4.7.2
The Eye
150
4.7.3
The Magnifying Glass
151
4.7.4
The Compound Microscope
152
4.7.5
The Telescope
153
4.7.6
The Exit Pupil
154
4.8
*Radiomerry
156
4.8.1
Extended Sources
159
4.8.2
Radiometry
of
Blackbody
Sources
161
4.8.3
Rayleigh-Jeans Theory and the Ultraviolet Catastrophe
163
4.8.4
Planck's Quantum Theory of
Blackbody
Radiation
165
4.9
"Optical Fibers
169
4.10
Thick Lenses
174
4.10.1
*Principal Points and Effective Focal Lengths of Thick Lenses
176
4.11
*Introduction to Matrix Methods in Paraxial Geometrical Optics
180
4.11.1
The Translation Matrix
180
4.11.2
The Refraction Matrix
182
4.11.3
The Reflection Matrix
184
4.11.4
The Ray Transfer Matrix
185
4.11.5
Location of Cardinal Points for an Optical System
189
Appendix: Calculation of the Jeans Number
197
Superposition and interference
199
5.1
Introduction
200
5.2
Superposition of Harmonic Waves
200
5.3
Interference Between Two Monochromatic Electromagnetic Waves
201
5.3.1
Linear Power Detection
202
5.3.2
Interference Between Beams with the Same Frequency
203
5.3.3
Thin-Film Interference
206
5.3.4
Quasi-Monochromatic Sources
210
5.3.5
Fringe Geometry
211
XII CONTENTS
5.3.6
Interference Between Beams with Different Frequencies
212
5.4
Fourier Analysis
218
5.4.1
Fourier Transforms
218
5.4.2
Position Space, k-Space Domain
219
5.4.3
Frequency-Time Domain
223
5.5
Properties of Fourier Transforms
224
5.5.1
Symmetry Properties
224
5.5.2
Linearity
225
5.5.3
Transform of a Transform
225
5.6
Wavepackets
226
5.7
Group and Phase Velocity
232
5.8
Interferometry
235
5.8.1
*Energy Conservation and Complementary Fringe Patterns
240
5.9
Single-Photon Interference
243
5.10
Multiple-Beam Interference
244
5.10.1
The Scanning Fabry-Perot Interferometer
247
5.11
Interference in Multilayer Films
251
5.11.1
Antireflection Films
255
5.11.2
High-Reflectance Films
257
5.12
Coherence
259
5.12.1
Temporal Coherence
260
5.12.2
Spatial Coherence
261
5.12.3
Michelson's Stellar Interferometer
264
5.12.4
Irradiance
Interferometry
265
5.12.5
Telescope Arrays
266
Appendix: Fourier Series
269
281
282
282
284
285
286
291
293
295
297
298
299
301
308
6.3.10
Apodization
311
6
Diffraction
6.1
Introduction
6.2
Huygens' Principle
6.2.1
Babinet's Principle
6.3 Fraunhofer
Diffraction
6.3.1
Single Slit
6.3.2
Rectangular Aperture
6.3.3
Circular Aperture
6.3.4
Optical Resolution
6.3.5
More on Stellar
Interferometry
6.3.6
Double Slit
6.3.7
N
Slits: The Diffraction Grating
6.3.8
The Diffraction Grating
6.3.9
Fraunhofer
Diffraction as a Fourier Transform
CONTENTS
ХІІІ
6.4 Fresnel
Diffraction
313
6.4.1 Fresnel
Zones
315
6.4.2
Holography
325
6.4.3
Numerical Analysis of Fresnel Diffraction with Circular Symmetry
327
6.4.4
Fresnel Diffraction from Apertures with Cartesian Symmetry
329
6.5
Introduction to Quantum Electrodynamics
338
6.5.1
Feynman's Interpretation
341
7
Lasers
345
7.1
Introduction
345
7.2
Energy Levels in Atoms, Molecules, and Solids
346
7.2.1
Atomic Energy Levels
346
7.2.2
Molecular Energy Levels
350
7.2.3
Solid-state Energy Bands
352
7.2.4
Semiconductor Devices
354
7.3
Stimulated Emission and Light Amplification
357
7.4
Laser Systems
361
7.4.1
Atomic Gas Lasers
363
7.4.2
Molecular Gas Lasers
364
7.4.3
Solid-State Lasers
367
7.4.4
Other Laser Systems
369
7.5
Longitudinal Cavity Modes
370
7.6
Frequency Stability
371
7.7
Introduction to Gaussian Beams
372
7.7.1
Overview of Gaussian Beam Properties
372
7.8
Derivation of Gaussian Beam Properties
375
7.8.1
Approximate Solutions to the Wave Equation
377
7.8.2
Paraxial Spherical Gaussian Beams
378
7.8.3
Gaussian Beam Focusing
380
7.8.4
Matrix Methods and the ABCD Law
384
7.9
Laser Cavities
385
7.9.1
Laser Cavity with Equal Mirror Curvatures
386
7.9.2
Laser Cavity with Unequal Mirror Curvatures
388
7.9.3
Stable Resonators
390
7.9.4
Traveling Wave Resonators
394
7.9.5
Unstable Resonators
394
7.9.6
Transverse Cavity Modes
395
8
Optical Imaging
399
8.1
Introduction
400
8.2
Abbe Theory of Image Formation
400
XIV CONTENTS
8.2.1 Phase
Contrast
Microscope
405
8.3
The Point
Spread Function
407
8.3.1
Coherent vs. Incoherent Images
407
8.3.2
Speckle
412
8.4
Resolving Power of Optical Instruments
413
8.5
Image Recording
415
8.5.1
Photographic Film
416
8.5.2
Digital Detector Arrays
417
8.6
Contrast Transfer Function
420
8.7
Spatial Filtering
422
8.8
Adaptive Optics
425
9
Polarization and Nonlinear Optics
431
9.1
Introduction
432
9.2
Linear Polarization
432
9.2.1
Linear Polarizers
433
9.2.2
Linear Polarizer Design
436
9.3
Birefringence
440
9.4
Circular and Elliptical Polarization
443
9.4.1
Wave Plates and Circular Polarizers
445
9.5
Jones Vectors and Matrices
449
9.5.1
Biréfringent
Colors
456
9.6
The Electro-optic Effect
458
9.6.1
Pockels Cells
459
9.6.2
Kerr Cells
461
9.7
Optical Activity
462
9.8
Faraday Rotation
463
9.9
Acousto-optic Effect
465
9.10
Nonlinear Optics
469
9.11
Harmonic Generation
471
9.11.1
Phase Conjugation Reflection by Degenerate Four-Wave Mixing
476
9.12
Frequency Mixing
478
References 4g3
Index
485 |
| any_adam_object | 1 |
| any_adam_object_boolean | 1 |
| author | Bennett, Charles A. |
| author_facet | Bennett, Charles A. |
| author_role | aut |
| author_sort | Bennett, Charles A. |
| author_variant | c a b ca cab |
| building | Verbundindex |
| bvnumber | BV022862899 |
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| dewey-tens | 530 - Physics |
| discipline | Physik |
| discipline_str_mv | Physik |
| format | Book |
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| genre | (DE-588)4173536-5 Patentschrift gnd-content |
| genre_facet | Patentschrift |
| id | DE-604.BV022862899 |
| illustrated | Illustrated |
| index_date | 2024-07-02T18:44:22Z |
| indexdate | 2024-07-09T21:07:12Z |
| institution | BVB |
| isbn | 0470122129 9780470122129 |
| language | English |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-016068102 |
| oclc_num | 159625274 |
| open_access_boolean | |
| owner | DE-703 DE-355 DE-BY-UBR DE-20 DE-29T DE-634 DE-11 |
| owner_facet | DE-703 DE-355 DE-BY-UBR DE-20 DE-29T DE-634 DE-11 |
| physical | XIV, 492 S. Ill., graph. Darst. |
| publishDate | 2008 |
| publishDateSearch | 2008 |
| publishDateSort | 2008 |
| publisher | Wiley |
| record_format | marc |
| spelling | Bennett, Charles A. Verfasser aut Principles of physical optics C. A. Bennett Hoboken, N.J. Wiley 2008 XIV, 492 S. Ill., graph. Darst. txt rdacontent n rdamedia nc rdacarrier Optique Optics Optik (DE-588)4043650-0 gnd rswk-swf (DE-588)4173536-5 Patentschrift gnd-content Optik (DE-588)4043650-0 s DE-604 Digitalisierung UB Regensburg application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=016068102&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis |
| spellingShingle | Bennett, Charles A. Principles of physical optics Optique Optics Optik (DE-588)4043650-0 gnd |
| subject_GND | (DE-588)4043650-0 (DE-588)4173536-5 |
| title | Principles of physical optics |
| title_auth | Principles of physical optics |
| title_exact_search | Principles of physical optics |
| title_exact_search_txtP | Principles of physical optics |
| title_full | Principles of physical optics C. A. Bennett |
| title_fullStr | Principles of physical optics C. A. Bennett |
| title_full_unstemmed | Principles of physical optics C. A. Bennett |
| title_short | Principles of physical optics |
| title_sort | principles of physical optics |
| topic | Optique Optics Optik (DE-588)4043650-0 gnd |
| topic_facet | Optique Optics Optik Patentschrift |
| url | http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=016068102&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA |
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