Handbook of optical systems: 3 Aberration theory and correction of optical systems
Gespeichert in:
| Format: | Buch |
|---|---|
| Sprache: | English |
| Veröffentlicht: |
Weinheim
Wiley-VCH
2007
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| Online-Zugang: | Inhaltsverzeichnis |
| Beschreibung: | XXIII, 756 S. zahlr. graph. Darst 25 cm |
| ISBN: | 9783527403790 3527403795 |
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| 245 | 1 | 0 | |a Handbook of optical systems |n 3 |p Aberration theory and correction of optical systems |c ed. by Herbert Gross |
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| adam_text | IMAGE 1
HANDBOOK OF OPTICAL SYSTEMS
EDITED BY HERBERT GROSS
VOLUME 3: ABERRATION THEORY AND CORRECTION OF OPTICAL SYSTEMS HERBERT
CROSS, HANNFRIED ZUEGGE, MARTIN PESCHKA, FRITZ BLECHINGER
B I C E N T E N N I AL
B I C E N T E N N IA
WILEY-VCH VERLAG GMBH & CO. KGAA
IMAGE 2
CONTENTS
PREFACE XIX
INTRODUCTION XXI
29 ABERRATIONS 1
29.1 INTRODUCTION 2
29.2 POWER SERIES EXPANSIONS 8
29.3 CHROMATIC ABERRATIONS 13
29.4 PRIMARY ABERRATIONS 16
29.4.1 APERTURE AND FIELD DEPENDENCE 16 29.4.2 SYMMETRY AND PERIODICITY
PROPERTIES 18 29.4.3 PRESENTATION OF ABERRATIONS AND THEIR IMPACT ON
IMAGE QUALITY 29.4.4 CALCULATION OF THE SEIDEL SUMS 29 29.4.5 STOP SHIFT
FORMULAE 36
29.4.6 SEVERAL ABERRATION EXPRESSIONS FROM THE SEIDEL SUMS 38 29.4.7
THIN LENS ABERRATIONS 41
29.5 PUPIL ABERRATIONS 45
29.6 HIGH-ORDER ABERRATIONS 50
29.6.1 FIFTH-ORDER ABERRATIONS 50 29.6.2 SEVENTH AND HIGHER-ORDER
ABERRATIONS 53 29.7 ZERNIKE POLYNOMIALS 55
29.8 SPECIAL ABERRATION FORMULAE 56
29.8.1 SINE CONDITION AND THE OFFENCE AGAINST THE SINE CONDITION 57
29.8.2 HERSCHEL CONDITION 60
29.8.3 APLANATISM AND ISOPLANATISM 61 29.8.4 ALDIS THEOREM 61
29.8.5 SPHERICAL ABERRATION, A SURFACE CONTRIBUTION FORMULA 64 29.8.6
APLANATIC SURFACE AND APLANATIC LENS 68 29.9 LITERATURE 70
30 IMAGE QUALITY CRITERIA 71
30.1 INTRODUCTION 74
30.2 GEOMETRICAL ABERRATIONS 76
HANDBOOK OFOPTICAL SYSTEMS: VOL. 3. ABERRATION THEORY AND CORRECTION
OFOPTICAL SYSTEMS. EDITED BY HERBERT GROSS COPYRIGHT 2007 WILEY-VCH
VERLAG GMBH & CO. KGAA, WEINHEIM
ISBN: 978-3-527-40379-0
IMAGE 3
XI CONTENTS
30.2.1 TRANSVERSE ABERRATIONS 76 30.2.2 SPOT DIAGRAMS 77
30.3 WAVE ABERRATIONS 80
INTRODUCTION 80
30.3.1 PV AND RMS VALUE OF THE WAVEFRONT 81 30.3.2 PV AND RMS VALUES OF
SIMPLE ABERRATIONS 83 30.3.3 INFLUENCE OF THE SPATIAL FREQUENCY 85 30.4
STREHL RATIO 87
30.4.1 INTRODUCTION 87
30.4.2 SIMPLE ANALYTICAL RELATIONS 89 30.4.3 APPROXIMATIONS OF THE
STREHL RATIO 91 30.5 SPECIAL CRITERIA 96
30.5.1 RAYLEIGH CRITERION 96
30.5.2 MARECHAL CRITERION 97
30.5.3 80% STREHL CRITERION 98
30.6 CRITERIA FOR PSF AND INTENSITY DISTRIBUTIONS 99 30.6.1 INTRODUCTION
99
30.6.2 APODIZATION 101
30.6.3 SPATIAL MOMENTS 102
30.6.4 KURTOSIS PARAMETER 104
30.6.5 BEAM QUALITY M 2 106
30.6.6 RELATION BETWEEN M 2 AND THE CONVENTIONAL CRITERIA 209 30.6.7
SPOT OR BEAM DIAMETER 111
30.7 POINT RESOLUTION 113
30.7.1 INTRODUCTION 113
30.7.2 INCOHERENT TWO-POINT RESOLUTION 116 30.7.3 COHERENT TWO-POINT
RESOLUTION 121 30.8 DEPTHOFFOCUS 124
30.8.1 BEST RECEIVING PLANE 127
30.8.2 DEFOCUS CRITERION OF FISHER 130 30.8.3 DEPTH OF FOCUS FOR VISUAL
DETECTION 131 30.9 MTF CRITERIA 132
30.9.1 INTRODUCTION 132
30.9.2 CONNECTION WITH OTHER CRITERIA 134 30.9.3 MTF FOR IDEAL AND
DEFOCUSED SYSTEMS 135 30.9.4 MTF FOR ABERRATIONS 138
30.9.5 SAGITTAL AND TANGENTIAL STRUCTURES 140 30.9.6 POLYCHROMATIC OTF
141 30.9.7 GEOMETRICAL APPROXIMATED TRANSFER FUNCTION GTF 142 30.9.8
PHASE TRANSFER FUNCTION PTF 144 30.9.9 ARGAND DIAGRAMM 146
30.9.10 CONTRAST VERSUS RESOLUTION 147 30.9.11 THRESHOLD MODULATION 152
30.9.12 HOPKINS FACTOR 153
30.9.13 AREA CRITERIA OF THE MTF 155
IMAGE 4
CONTENTS I XI
30.9.14 COHERENT TRANSFER FUNCTION 156 30.9.15 TEST CHARTS 157
30.9.16 IMAGE EXAMPLES 161 30.10 EDGE CRITERIA 163
30.10.1 EDGEWIDTH 163
30.10.2 EDGE STEEPNESS 267
30.10.3 ACUTANCE AND EDGE DEFECT 268 30.11 LINE CRITERIA 268
30.11.1 RESOLUTION OF LINES 168 30.11.2 LSFCRITERIONOFSTRUVE 270
30.11.3 BOSSUNG PLOTS 272
30.12 ENCIRCLED ENERGY 275
30.12.1 INTRODUCTION 275
30.12.2 ENERGY CURVE OF THE AIRY PATTERN 277 30.12.3 ENSQUARED ENERGY
277 30.12.4 DISPLACED ENERGY CRITERION 278
30.13 SPECIAL CRITERIA 279
30.13.1 RELATIVE CEILING 279 30.13.2 FIDELITY 280
30.13.3 STRUCTURAL CONTENT 280
30.13.4 CORRELATION 282
30.13.5 RELATIONS AND COMPARISON BETWEEN THE CRITERIA 282 30.14
DISTORTION 282
30.15 COLOR ABERRATIONS 287
30.15.1 TRANSVERSE COLOR 287 30.15.2 LONGITUDINAL COLOR 288 30.16
TRANSMISSION AND ILLUMINATION 292 30.16.1 ILLUMINATION FALL-OFF 292
30.16.2 SPECIAL ILLUMINATION PROFILES 293 30.17
FIELDDEPENDENCEOFTHEQUALITY 294
30.18 STATISTICAL ABERRATIONS 299
30.18.1 INTRODUCTION 299
30.18.2 STATISTICAL SURFACES 299 30.18.3 STATISTICAL WAVE ABERRATIONS
202 30.18.4 POINT SPREAD FUNCTION IN THE PRESENCE OF STATISTICAL
ABERRATIONS 202 30.18.5 TRANSFER FUNCTION IN THE PRESENCE OF STATISTICAL
ABERRATIONS 204
30.18.6 ATMOSPHERIC PERTURBATIONS 205 30.19 SPECIAL ASPECTS 207
30.19.1 COMPLETE CHAIN OF IMAGE FORMATION 207 30.19.2 DISCRETIZARION
PROBLEMS 207 30.19.3 MOTION BLUR 208
30.19.4 SPECIAL IMAGING MODES 209 30.19.5 PARASITIC LIGHT 209 30.19.6
POLARIZATION 209
30.20 LITERATURE 222
IMAGE 5
XII CONTENTS
31 CORRECTION OF ABERRATIONS 225
31.1 STRATEGIES 226
31.1.1 INTRODUCTION 216
31.1.2 LENS BENDING 218
31.1.3 POWER SPLITTING 219
31.1.4 POWER COMBINATION 229
31.1.5 DISTANCES 220
31.1.6 STOP POSITION 220
31.1.7 REFRACTIVE INDEX 222
31.1.8 DISPERSION 222
31.1.9 RELATIVE PARTIAL DISPERSION 222 31.1.10 GRIN, GRADIENT INDEX
MATERIAL 222 31.1.11 CEMENTED SURFACE 223 31.1.12 APLANATIC SURFACE 223
31.1.13 ASPHERICAL SURFACE 223 31.1.14 MIRROR 224
31.1.15 DIFFRACTIVE SURFACE 224 31.1.16 SYMMETRY PRINCIPLE 225 31.1.17
FIELD LENS 226
31.2 MONOCHROMATIC ABERRATIONS 226 31.2.1 SPHERICAL ABERRATION 226
31.2.2 COMA 242
31.2.3 ASTIGMATISM 250
31.2.4 PETZVAL CURVATURE 252
31.2.5 DISTORTION 262
31.2.6 HIGH-ORDER ABERRATIONS 265 31.3 CHROMATIC ABERRATIONS 268
31.3.1 AXIAL COLOR AND SECONDARY SPECTRUM 269 31.3.2 LATERAL COLOR 280
31.3.3 SPHEROCHROMATISM 283
31.4 COEXISTENCE OF ABERRATIONS 285
31.5 LITERATURE 289
32 PRINCIPLES OF OPTIMIZATION 292
32.1 INTRODUCTION 293
32.2 NUMERICS OF OPTIMIZATION 295
32.2.1 NOTATION 295
32.2.2 LINEAR MATRIX ALGEBRA 297 32.2.3 LOCAL EXPANSION OF THE ERROR
FUNCTION 299 32.2.4 THE CONTROL FUNCTION 300
32.2.5 ONE-DIMENSIONAL MINIMUM SEARCH 302 32.2.6 SIGNIFICANCE OF THE
RESULT 304 32.2.7 TERMINATION OF THE ITERATION 305 32.2.8 EFFICIENCY
OFVARIABLES AND WEIGHTING FACTORS 305 32.2.9 PERFORMANCE OF AN ALGORITHM
307
IMAGE 6
CONTENTS XIII
32.2.10 NUMERICAL CALCULATION OF DERIVATIVES 307 32.3 CONSTRAINTS 309
32.3.1 INTRODUCTION 309
32.3.2 KUHN-TUCKER CONDITIONS 312 32.3.3 PENALTY FUNCTION 313
32.3.4 BARRIER METHODS 325
32.4 LOCAL SOLUTION METHODS 316
32.4.1 INTRODUCTION 326
32.4.2 METHOD OF STEEPEST DESCENT 317
32.4.3 METHOD OF NEWTON-RAPHSON WITHOUT CONSTRAINTS 329 32.4.4 DAMPED
LEAST-SQUARES METHOD WITHOUT CONSTRAINTS 320 32.4.5 DAMPED LEAST-SQUARES
METHOD WITH CONSTRAINTS 322 32.4.6 CONJUGATE GRADIENT METHOD 323 32.4.7
METHOD OF DAVIDON, FLETCHER AND POWELL 324
32.4.8 METHOD OF LEVENBERG-MARQUARDT 325 32.4.9 ORTHOGONALIZATION OFTHE
SYSTEM MATRIX 326 32.4.10 DERIVATIVE-FREE SIMPLEX METHODS 327 32.4.11
COMPARISON OF ALGORITHMS 329 32.5 GLOBAL OPTIMIZATION METHODS 330
32.5.1 INTRODUCTION 330
32.5.2 SIMULATED ANNEALING 332
32.5.3 GENETIC OPTIMIZATION 335
32.6 OPTIMIZATION OFOPTICAL SYSTEMS 337
32.6.1 INTRODUCTION 337
32.6.2 EXAMPLE 1: BENDING OF A THIN LENS 338 32.6.3 EXAMPLE 2:
ACHROMATIC DOUBLET 339 32.6.4 PARAMETERS OFOPTICAL SYSTEMS 347 32.6.5
CONSTRAINTS OF OPTICAL SYSTEMS 347
32.6.6 MERIT FUNCTION 349
32.6.7 SPECIAL ASPECTS 350
32.7 STARTING SYSTEMS IN LENS DESIGN 353
32.7.1 INTRODUCTION 353
32.7.2 THIN LENS START SYSTEM 354
32.7.3 TRUCTURAL APPROACH ACCORDING TO SHAFER 355 32.8 CONTROLLING THE
OPTIMIZATION PROCESS 356 32.8.1 THE COMPLETE DESIGN PROCESS 356 32.8.2
STRUCTURAL CHANGES IN THE SYSTEM 358
32.8.3 EXPERT SYSTEMS 359
32.8.4 GLOBAL OPTIMIZATION IN OPTICAL DESIGN 360 32.8.5 THE SADDLE POINT
METHOD OF BOCIORT 362 32.8.6 ISSHIKIS METHOD OFTHE GLOBAL EXPLORER 365
32.8.7 ADAPTIVE CORRECTION METHOD ACCORDING TO GLATZEL 368
32.9 LITERATURE 369
IMAGE 7
XIV CONTENTS
33 OPTIMIZATION PROCESS 371
33.1 GENERAL ASPECTS 372
33.1.1 INTRODUCTION 372
33.1.2 ADDITION AND REMOVAL OF A LENS 372 33.1.3 METHODS OF IMPROVING A
DESIGN 377 33.1.4 ZERO POWER OPERATIONS 378
33.1.5 SUBSTITUTION OF STANDARD RADII 379 33.2 PROPERTIES OF MICROSCOPE
OBJECTIVE LENSES 382 33.2.1 GENERAL DISCUSSION OF MICRO-OBJECTIVE LENSES
382 33.2.2 SETUP OF A MICRO-OBJECTIVE LENS 383 33.2.3 PERFORMANCE AND
QUALITYOF MICRO-OBJECTIVE LENSES 385 33.2.4 SPECIAL ASPECTS 386
33.2.5 ANALYSIS OF SEVERAL EXISTING DESIGN SOLUTIONS 391 33.3
DEVELOPMENT OFA MONOCHROMATIC HIGH NA MICROSCOPE LENS 401 33.3.1
SPECIFICATION AND STRATEGY 401 33.3.2 INITIAL LENS SETUP 403
33.3.3 INCREASING THE NUMERICAL APERTURE 403 33.3.4 IMPROVING THE
ON-AXIS PERFORMANCE 407 33.3.5 EXTENDING THE FIELD OF VIEW 408 33.3.6
IMPROVEMENT OF THE PERFORMANCE I 410 33.3.7 REMOVING UNNECESSARY
SURFACES 411 33.3.8 IMPROVEMENT OF THE PERFORMANCE II 413 33.3.9
IMPROVING THE FIELD UNIFORMITY 414 33.3.10 OBTAINING THE DESIRED WORKING
DISTANCE 415 33.3.11 MAKING THE SYSTEM TELECENTRIC 417
33.3.12 DOCUMENTATION OF THE FINAL DESIGN 418 33.3.13 OVERVIEW OF THE
DESIGN STAGES 428 33.4 LITERATURE 429
34 SPECIAL CORRECTION FEATURES 431 34.1 ASPHERICAL SURFACES 433
34.1.1 INTRODUCTION 433
34.1.2 CLASSIFICATION OF ASPHERICAL SURFACES 434 34.1.3 EXACT MIRROR
ASPHERES FOR STIGMATIC IMAGING 434 34.1.4 REFRACTING SURFACE CORRECTED
FOR SPHERICAL ABERRATION 435 34.1.5 POLYNOMIAL ASPHERICAL SURFACES 436
34.1.6 SCALING AND CONVERSION OF ASPHERICAL COEFFICIENTS 438 34.1.7 THE
HIGHER-ORDER PROBLEM 439 34.1.8 APLANATIC IMAGING WITH ASPHERES 440
34.1.9 SEIDEL CONTRIBUTIONS OF ASPHERES 443
34.1.10 BEST LOCATION FOR AN ASPHERE INSIDE A SYSTEM 444 34.1.11 CHOICE
OF THE EXPANSION ORDER 452 34.1.12 REALIZATION ASPECTS FOR ASPHERES 454
34.1.13 FREE-FORM ASPHERES 456 34.2 GRADIENT INDEX MEDIA 463
IMAGE 8
34.2.1 INTRODUCTION 463
34.2.2 GRIN LENSES WITH RADIAL PARABOLIC INDEX PROFILE 467 34.2.3
PERFECT SOLUTIONS 469
34.2.4 WOOD OR ROD LENSES 470
34.2.5 AXIAL GRIN MEDIA 472
34.2.6 SEIDEL ABERRATIONS OFA GRIN LENS WITH ROTATIONAL SYMMETRY 475
34.2.7 SEIDEL ABERRATIONS OF RADIAL GRIN MEDIA 476 34.2.8 SEIDEL
ABERRATIONS OF AXIAL GRIN MEDIA 477 34.2.9 ABERRATIONS OF RADIAL GRIN
MEDIA 478 34.2.10 ABERRATIONS OF AXIAL GRIN LENSES 481
34.2.11 GRADIUM MEDIA 482 34.2.12 EXAMPLES OF RADIAL AND AXIAL GRADIENT
SYSTEMS 485 34.2.13 EXAMPLES OF GRADIUM SYSTEMS 487 34.2.14 CHROMATIC
ABERRATIONS 489 34.2.15 PRINCIPLES FOR CORRECTION OF GRIN SYSTEMS 491
34.2.16 CORRECTION WITH GRADIUM LENSES 493 34.2.17 GENERAL APPLICATION
ASPECTS OF GRIN LENSES 495 34.3 SYSTEMS WITH DIFFRACTIVE ELEMENTS 495
34.3.1 INTRODUCTION 495
34.3.2 WORKING PRINCIPLE OF DIFFRACTIVE ELEMENTS 496 34.3.3 TYPES OF
DIFFRACTIVE ELEMENT 499 34.3.4 EQUIVALENT ASPHERICAL PHASE MASK 500
34.3.5 SWEATT MODEL 502
34.3.6 DISPERSION 502
34.3.7 FRESNEL ZONE LENS 503
34.3.8 ACHROMATIC HYBRID LENS 505 34.3.9 MULTI-ORDER DIFFRACTIVE LENSES
509 34.3.10 SEIDEL ABERRATIONS 511 34.3.11 DIFFRACTIVE SINGLET 513
34.3.12 DIFFRACTION EFFICIENCY 519 34.3.13 DIFFRACTIVE OPTICS FOR BROAD
SPECTRAL RANGES 522
34.3.14 ATHERMALIZATION WITH DIFFRACTIVE ELEMENTS 528 34.3.15 TRANSITION
BETWEEN REFRACTIVE AND DIFFRACTIVE SURFACES 529 34.3.16 OPTICAL DESIGN
WITH DIFFRACTIVE ELEMENTS 532 34.3.17 PRACTICAL ASPECTS AND TOLERANCES
533
34.3.18 APPLICATIONS 538 34.3.19 FURTHER EXAMPLES 539 34.4
NON-AXISYMMETRICAL SYSTEMS 543 34.4.1 INTRODUCTION 543
34.4.2 AXIS RAY AND 3D GEOMETRY 546 34.4.3 IMAGE TILT AND ANAMORPHISM
549 34.4.4 SECOND-ORDER ENVIRONMENTAL PROPAGATION AROUND THE AXIS RAY
552 34.4.5 VECTOR ABERRATION THEORY OF TILTED AXISYMMETRICAL COMPONENTS
555
34.4.6 THIRD-ORDER ABERRATIONS FOR TILTED COMPONENT SYSTEMS 558 34.4.7
GENERAL DISTORTION 562
IMAGE 9
XVI CONTENTS
34.4.8 GENERALIZED ABERRATION THEORY FOR PLANE SYMMETRIE SYSTEMS 563
34.4.9 SYSTEMS WITH GENERAL 3D GEOMETRY 564 34.4.10 EXAMPLES OF
ANAMORPHOTIC SYSTEMS 566 34.4.11 SCHIEFSPIEGIER TELESCOPES 571 34.4.12
EXAMPLE OF A GENERAL 3D SYSTEM 579 34.4.13 EXAMPLE WITH REFRACTIVE
COMPONENT 584 34.5 LITERATURE 587
35 TOLERANCING 595
35.1 INTRODUCTION 597
35.2 TOLERANCES FOR OPTICAL ELEMENTS AND OPTICAL SYSTEMS 600 35.2.1
INTRODUCTION TO TOLERANCES IN THE INTERNATIONAL STANDARD ISO-10110 600
35.2.2 STRESS BIREFRINGENCE 601
35.2.3 BUBBLES AND INCLUSIONS 603
35.2.4 INHOMOGENEITY AND STRIAE 602
35.2.5 SURFACE-FORM TOLERANCES 605 35.2.6 SPATIAL FREQUENCIES OF SURFACE
ERRORS 610 35.2.7 SURFACE-FORM TOLERANCES FOR ASPHERICAL SURFACES 613
35.2.8 SURFACE IMPERFECTION TOLERANCES 615
35.2.9 SURFACE TEXTURE 618
35.2.10 CENTERING TOLERANCES 630 35.3 DECENTER AND TILT TOLERANCES 631
35.3.1 CENTERING OF LENSES WITH SPHERICAL SURFACES 632 35.3.2 CENTERING
ERRORS IN ASPHERICAL LENSES 636 35.3.3 TYPICAL TYPES OF CENTERING ERRORS
IN PRACTICAL TOLERANCING 637 35.3.4 CONTROL OF CENTERING ERRORS IN
BONDING PROCESSES 639
35.3.5 CENTERING ERRORS OF LENSES IN MOUNTS 640 35.4 TOLERANCE COSTS 650
35.5 TOLERANCES, COMPENSATORS AND ADJUSTMENT 652 35.5.1 COMPENSATORS FOR
TYPICAL ABERRATIONS 653 35.5.2 MODELING OF ADJUSTMENT 657 35.5.3
EXAMPLE: ADJUSTMENT OF SPHERICAL ABERRATION, ON-AXIS ASTIGMATISM
AND ON-AXIS COMA 660 35.6 TOLERANCE DISTRIBUTIONS 667
35.7 PRACTICAL TOLERANCING 671
35.7.1 ASSIGNING TOLERANCES BY SENSITIVITY ANALYSIS 671 35.7.2
SENSITIVITY ANALYSIS 672 35.7.3 STATISTICAL SIMULATIONS 677 35.7.4
INVERSE TOLERANCING 685
35.8 PRISM TOLERANCES 690
35.8.1 INTRODUCTION 690
35.8.2 ANGLE ERRORS OF PRISMS IN THE PRINCIPAL PLANE 693 35.8.3
PRINCIPAL ANGLE ERRORS OF SPECIAL PRISMS 693 35.8.4 PYRAMIDAL ERROR 698
35.8.5 PYRAMIDAL ERRORS IN SPECIAL PRISMS 701
IMAGE 10
CONTENTS XVII
35.8.6 CALCULATION OF IMAGE ROTATION 70 35.8.7 ERROR IN THE ORIENTATION
OFA PRISM 706 35.8.8 ROOF-ANGLE TOLERANCES 706 35.8.9 ANGLE ERRORS IN A
CORNER CUBE PRISM 710 35.8.10 ASTIGMATISM TOLERANCE OF PRISMS 712 35.9
LITERATURE 714
A2 OPTICAL DESIGN SOFTWARE OPTALIX 717 A2.1 INTRODUCTION 718
A2.2 PROGRAM USER INTERFACE 718
A2.2.1 COMMAND LINE 719
A2.2.2 FUNCTIONS AND ARITHMETIC EXPRESSIONS 721 A2.2.3 LENS DATABASE
ITEMS 721
A2.3 CONFIGURATION AND SYSTEM DATA 722
A2.3.1 FIELDS 722
A2.3.2 WAVELENGTHS 723
A2.3.3 APERTURES 724
A2.4 SURFACE DATA 724
A2.4.1 SURFACE EDITOR 725
A2.4.2 SURFACE TYPES 726
A2.4.3 SURFACE APERTURES 728
A2.5 WORKED EXAMPLES 731
A2.5.1 TILTED SURFACES EXAMPLE 731 A2.5.2 ASPHERICAL SURFACES EXAMPLE
733 A2.5.3 ZOOM EXAMPLE 734
A2.5.4 GLOBAL SURFACE REFERENCES 737 A2.6 OPTICAL DESIGN IMPORT AND
EXPORT 739
A2.7 OPTALIX-PRO CAPABILITIES 742
A2.8 OBTAINING OPTALIX-LT 747
INDEX 749
|
| adam_txt |
IMAGE 1
HANDBOOK OF OPTICAL SYSTEMS
EDITED BY HERBERT GROSS
VOLUME 3: ABERRATION THEORY AND CORRECTION OF OPTICAL SYSTEMS HERBERT
CROSS, HANNFRIED ZUEGGE, MARTIN PESCHKA, FRITZ BLECHINGER
B I C E N T E N N I AL
B I C E N T E N N IA
WILEY-VCH VERLAG GMBH & CO. KGAA
IMAGE 2
CONTENTS
PREFACE XIX
INTRODUCTION XXI
29 ABERRATIONS 1
29.1 INTRODUCTION 2
29.2 POWER SERIES EXPANSIONS 8
29.3 CHROMATIC ABERRATIONS 13
29.4 PRIMARY ABERRATIONS 16
29.4.1 APERTURE AND FIELD DEPENDENCE 16 29.4.2 SYMMETRY AND PERIODICITY
PROPERTIES 18 29.4.3 PRESENTATION OF ABERRATIONS AND THEIR IMPACT ON
IMAGE QUALITY 29.4.4 CALCULATION OF THE SEIDEL SUMS 29 29.4.5 STOP SHIFT
FORMULAE 36
29.4.6 SEVERAL ABERRATION EXPRESSIONS FROM THE SEIDEL SUMS 38 29.4.7
THIN LENS ABERRATIONS 41
29.5 PUPIL ABERRATIONS 45
29.6 HIGH-ORDER ABERRATIONS 50
29.6.1 FIFTH-ORDER ABERRATIONS 50 29.6.2 SEVENTH AND HIGHER-ORDER
ABERRATIONS 53 29.7 ZERNIKE POLYNOMIALS 55
29.8 SPECIAL ABERRATION FORMULAE 56
29.8.1 SINE CONDITION AND THE OFFENCE AGAINST THE SINE CONDITION 57
29.8.2 HERSCHEL CONDITION 60
29.8.3 APLANATISM AND ISOPLANATISM 61 29.8.4 ALDIS THEOREM 61
29.8.5 SPHERICAL ABERRATION, A SURFACE CONTRIBUTION FORMULA 64 29.8.6
APLANATIC SURFACE AND APLANATIC LENS 68 29.9 LITERATURE 70
30 IMAGE QUALITY CRITERIA 71
30.1 INTRODUCTION 74
30.2 GEOMETRICAL ABERRATIONS 76
HANDBOOK OFOPTICAL SYSTEMS: VOL. 3. ABERRATION THEORY AND CORRECTION
OFOPTICAL SYSTEMS. EDITED BY HERBERT GROSS COPYRIGHT 2007 WILEY-VCH
VERLAG GMBH & CO. KGAA, WEINHEIM
ISBN: 978-3-527-40379-0
IMAGE 3
XI CONTENTS
30.2.1 TRANSVERSE ABERRATIONS 76 30.2.2 SPOT DIAGRAMS 77
30.3 WAVE ABERRATIONS 80
INTRODUCTION 80
30.3.1 PV AND RMS VALUE OF THE WAVEFRONT 81 30.3.2 PV AND RMS VALUES OF
SIMPLE ABERRATIONS 83 30.3.3 INFLUENCE OF THE SPATIAL FREQUENCY 85 30.4
STREHL RATIO 87
30.4.1 INTRODUCTION 87
30.4.2 SIMPLE ANALYTICAL RELATIONS 89 30.4.3 APPROXIMATIONS OF THE
STREHL RATIO 91 30.5 SPECIAL CRITERIA 96
30.5.1 RAYLEIGH CRITERION 96
30.5.2 MARECHAL CRITERION 97
30.5.3 80% STREHL CRITERION 98
30.6 CRITERIA FOR PSF AND INTENSITY DISTRIBUTIONS 99 30.6.1 INTRODUCTION
99
30.6.2 APODIZATION 101
30.6.3 SPATIAL MOMENTS 102
30.6.4 KURTOSIS PARAMETER 104
30.6.5 BEAM QUALITY M 2 106
30.6.6 RELATION BETWEEN M 2 AND THE CONVENTIONAL CRITERIA 209 30.6.7
SPOT OR BEAM DIAMETER 111
30.7 POINT RESOLUTION 113
30.7.1 INTRODUCTION 113
30.7.2 INCOHERENT TWO-POINT RESOLUTION 116 30.7.3 COHERENT TWO-POINT
RESOLUTION 121 30.8 DEPTHOFFOCUS 124
30.8.1 BEST RECEIVING PLANE 127
30.8.2 DEFOCUS CRITERION OF FISHER 130 30.8.3 DEPTH OF FOCUS FOR VISUAL
DETECTION 131 30.9 MTF CRITERIA 132
30.9.1 INTRODUCTION 132
30.9.2 CONNECTION WITH OTHER CRITERIA 134 30.9.3 MTF FOR IDEAL AND
DEFOCUSED SYSTEMS 135 30.9.4 MTF FOR ABERRATIONS 138
30.9.5 SAGITTAL AND TANGENTIAL STRUCTURES 140 30.9.6 POLYCHROMATIC OTF
141 30.9.7 GEOMETRICAL APPROXIMATED TRANSFER FUNCTION GTF 142 30.9.8
PHASE TRANSFER FUNCTION PTF 144 30.9.9 ARGAND DIAGRAMM 146
30.9.10 CONTRAST VERSUS RESOLUTION 147 30.9.11 THRESHOLD MODULATION 152
30.9.12 HOPKINS FACTOR 153
30.9.13 AREA CRITERIA OF THE MTF 155
IMAGE 4
CONTENTS I XI
30.9.14 COHERENT TRANSFER FUNCTION 156 30.9.15 TEST CHARTS 157
30.9.16 IMAGE EXAMPLES 161 30.10 EDGE CRITERIA 163
30.10.1 EDGEWIDTH 163
30.10.2 EDGE STEEPNESS 267
30.10.3 ACUTANCE AND EDGE DEFECT 268 30.11 LINE CRITERIA 268
30.11.1 RESOLUTION OF LINES 168 30.11.2 LSFCRITERIONOFSTRUVE 270
30.11.3 BOSSUNG PLOTS 272
30.12 ENCIRCLED ENERGY 275
30.12.1 INTRODUCTION 275
30.12.2 ENERGY CURVE OF THE AIRY PATTERN 277 30.12.3 ENSQUARED ENERGY
277 30.12.4 DISPLACED ENERGY CRITERION 278
30.13 SPECIAL CRITERIA 279
30.13.1 RELATIVE CEILING 279 30.13.2 FIDELITY 280
30.13.3 STRUCTURAL CONTENT 280
30.13.4 CORRELATION 282
30.13.5 RELATIONS AND COMPARISON BETWEEN THE CRITERIA 282 30.14
DISTORTION 282
30.15 COLOR ABERRATIONS 287
30.15.1 TRANSVERSE COLOR 287 30.15.2 LONGITUDINAL COLOR 288 30.16
TRANSMISSION AND ILLUMINATION 292 30.16.1 ILLUMINATION FALL-OFF 292
30.16.2 SPECIAL ILLUMINATION PROFILES 293 30.17
FIELDDEPENDENCEOFTHEQUALITY 294
30.18 STATISTICAL ABERRATIONS 299
30.18.1 INTRODUCTION 299
30.18.2 STATISTICAL SURFACES 299 30.18.3 STATISTICAL WAVE ABERRATIONS
202 30.18.4 POINT SPREAD FUNCTION IN THE PRESENCE OF STATISTICAL
ABERRATIONS 202 30.18.5 TRANSFER FUNCTION IN THE PRESENCE OF STATISTICAL
ABERRATIONS 204
30.18.6 ATMOSPHERIC PERTURBATIONS 205 30.19 SPECIAL ASPECTS 207
30.19.1 COMPLETE CHAIN OF IMAGE FORMATION 207 30.19.2 DISCRETIZARION
PROBLEMS 207 30.19.3 MOTION BLUR 208
30.19.4 SPECIAL IMAGING MODES 209 30.19.5 PARASITIC LIGHT 209 30.19.6
POLARIZATION 209
30.20 LITERATURE 222
IMAGE 5
XII CONTENTS
31 CORRECTION OF ABERRATIONS 225
31.1 STRATEGIES 226
31.1.1 INTRODUCTION 216
31.1.2 LENS BENDING 218
31.1.3 POWER SPLITTING 219
31.1.4 POWER COMBINATION 229
31.1.5 DISTANCES 220
31.1.6 STOP POSITION 220
31.1.7 REFRACTIVE INDEX 222
31.1.8 DISPERSION 222
31.1.9 RELATIVE PARTIAL DISPERSION 222 31.1.10 GRIN, GRADIENT INDEX
MATERIAL 222 31.1.11 CEMENTED SURFACE 223 31.1.12 APLANATIC SURFACE 223
31.1.13 ASPHERICAL SURFACE 223 31.1.14 MIRROR 224
31.1.15 DIFFRACTIVE SURFACE 224 31.1.16 SYMMETRY PRINCIPLE 225 31.1.17
FIELD LENS 226
31.2 MONOCHROMATIC ABERRATIONS 226 31.2.1 SPHERICAL ABERRATION 226
31.2.2 COMA 242
31.2.3 ASTIGMATISM 250
31.2.4 PETZVAL CURVATURE 252
31.2.5 DISTORTION 262
31.2.6 HIGH-ORDER ABERRATIONS 265 31.3 CHROMATIC ABERRATIONS 268
31.3.1 AXIAL COLOR AND SECONDARY SPECTRUM 269 31.3.2 LATERAL COLOR 280
31.3.3 SPHEROCHROMATISM 283
31.4 COEXISTENCE OF ABERRATIONS 285
31.5 LITERATURE 289
32 PRINCIPLES OF OPTIMIZATION 292
32.1 INTRODUCTION 293
32.2 NUMERICS OF OPTIMIZATION 295
32.2.1 NOTATION 295
32.2.2 LINEAR MATRIX ALGEBRA 297 32.2.3 LOCAL EXPANSION OF THE ERROR
FUNCTION 299 32.2.4 THE CONTROL FUNCTION 300
32.2.5 ONE-DIMENSIONAL MINIMUM SEARCH 302 32.2.6 SIGNIFICANCE OF THE
RESULT 304 32.2.7 TERMINATION OF THE ITERATION 305 32.2.8 EFFICIENCY
OFVARIABLES AND WEIGHTING FACTORS 305 32.2.9 PERFORMANCE OF AN ALGORITHM
307
IMAGE 6
CONTENTS XIII
32.2.10 NUMERICAL CALCULATION OF DERIVATIVES 307 32.3 CONSTRAINTS 309
32.3.1 INTRODUCTION 309
32.3.2 KUHN-TUCKER CONDITIONS 312 32.3.3 PENALTY FUNCTION 313
32.3.4 BARRIER METHODS 325
32.4 LOCAL SOLUTION METHODS 316
32.4.1 INTRODUCTION 326
32.4.2 METHOD OF STEEPEST DESCENT 317
32.4.3 METHOD OF NEWTON-RAPHSON WITHOUT CONSTRAINTS 329 32.4.4 DAMPED
LEAST-SQUARES METHOD WITHOUT CONSTRAINTS 320 32.4.5 DAMPED LEAST-SQUARES
METHOD WITH CONSTRAINTS 322 32.4.6 CONJUGATE GRADIENT METHOD 323 32.4.7
METHOD OF DAVIDON, FLETCHER AND POWELL 324
32.4.8 METHOD OF LEVENBERG-MARQUARDT 325 32.4.9 ORTHOGONALIZATION OFTHE
SYSTEM MATRIX 326 32.4.10 DERIVATIVE-FREE SIMPLEX METHODS 327 32.4.11
COMPARISON OF ALGORITHMS 329 32.5 GLOBAL OPTIMIZATION METHODS 330
32.5.1 INTRODUCTION 330
32.5.2 SIMULATED ANNEALING 332
32.5.3 GENETIC OPTIMIZATION 335
32.6 OPTIMIZATION OFOPTICAL SYSTEMS 337
32.6.1 INTRODUCTION 337
32.6.2 EXAMPLE 1: BENDING OF A THIN LENS 338 32.6.3 EXAMPLE 2:
ACHROMATIC DOUBLET 339 32.6.4 PARAMETERS OFOPTICAL SYSTEMS 347 32.6.5
CONSTRAINTS OF OPTICAL SYSTEMS 347
32.6.6 MERIT FUNCTION 349
32.6.7 SPECIAL ASPECTS 350
32.7 STARTING SYSTEMS IN LENS DESIGN 353
32.7.1 INTRODUCTION 353
32.7.2 THIN LENS START SYSTEM 354
32.7.3 TRUCTURAL APPROACH ACCORDING TO SHAFER 355 32.8 CONTROLLING THE
OPTIMIZATION PROCESS 356 32.8.1 THE COMPLETE DESIGN PROCESS 356 32.8.2
STRUCTURAL CHANGES IN THE SYSTEM 358
32.8.3 EXPERT SYSTEMS 359
32.8.4 GLOBAL OPTIMIZATION IN OPTICAL DESIGN 360 32.8.5 THE SADDLE POINT
METHOD OF BOCIORT 362 32.8.6 ISSHIKIS METHOD OFTHE GLOBAL EXPLORER 365
32.8.7 ADAPTIVE CORRECTION METHOD ACCORDING TO GLATZEL 368
32.9 LITERATURE 369
IMAGE 7
XIV CONTENTS
33 OPTIMIZATION PROCESS 371
33.1 GENERAL ASPECTS 372
33.1.1 INTRODUCTION 372
33.1.2 ADDITION AND REMOVAL OF A LENS 372 33.1.3 METHODS OF IMPROVING A
DESIGN 377 33.1.4 ZERO POWER OPERATIONS 378
33.1.5 SUBSTITUTION OF STANDARD RADII 379 33.2 PROPERTIES OF MICROSCOPE
OBJECTIVE LENSES 382 33.2.1 GENERAL DISCUSSION OF MICRO-OBJECTIVE LENSES
382 33.2.2 SETUP OF A MICRO-OBJECTIVE LENS 383 33.2.3 PERFORMANCE AND
QUALITYOF MICRO-OBJECTIVE LENSES 385 33.2.4 SPECIAL ASPECTS 386
33.2.5 ANALYSIS OF SEVERAL EXISTING DESIGN SOLUTIONS 391 33.3
DEVELOPMENT OFA MONOCHROMATIC HIGH NA MICROSCOPE LENS 401 33.3.1
SPECIFICATION AND STRATEGY 401 33.3.2 INITIAL LENS SETUP 403
33.3.3 INCREASING THE NUMERICAL APERTURE 403 33.3.4 IMPROVING THE
ON-AXIS PERFORMANCE 407 33.3.5 EXTENDING THE FIELD OF VIEW 408 33.3.6
IMPROVEMENT OF THE PERFORMANCE I 410 33.3.7 REMOVING UNNECESSARY
SURFACES 411 33.3.8 IMPROVEMENT OF THE PERFORMANCE II 413 33.3.9
IMPROVING THE FIELD UNIFORMITY 414 33.3.10 OBTAINING THE DESIRED WORKING
DISTANCE 415 33.3.11 MAKING THE SYSTEM TELECENTRIC 417
33.3.12 DOCUMENTATION OF THE FINAL DESIGN 418 33.3.13 OVERVIEW OF THE
DESIGN STAGES 428 33.4 LITERATURE 429
34 SPECIAL CORRECTION FEATURES 431 34.1 ASPHERICAL SURFACES 433
34.1.1 INTRODUCTION 433
34.1.2 CLASSIFICATION OF ASPHERICAL SURFACES 434 34.1.3 EXACT MIRROR
ASPHERES FOR STIGMATIC IMAGING 434 34.1.4 REFRACTING SURFACE CORRECTED
FOR SPHERICAL ABERRATION 435 34.1.5 POLYNOMIAL ASPHERICAL SURFACES 436
34.1.6 SCALING AND CONVERSION OF ASPHERICAL COEFFICIENTS 438 34.1.7 THE
HIGHER-ORDER PROBLEM 439 34.1.8 APLANATIC IMAGING WITH ASPHERES 440
34.1.9 SEIDEL CONTRIBUTIONS OF ASPHERES 443
34.1.10 BEST LOCATION FOR AN ASPHERE INSIDE A SYSTEM 444 34.1.11 CHOICE
OF THE EXPANSION ORDER 452 34.1.12 REALIZATION ASPECTS FOR ASPHERES 454
34.1.13 FREE-FORM ASPHERES 456 34.2 GRADIENT INDEX MEDIA 463
IMAGE 8
34.2.1 INTRODUCTION 463
34.2.2 GRIN LENSES WITH RADIAL PARABOLIC INDEX PROFILE 467 34.2.3
PERFECT SOLUTIONS 469
34.2.4 WOOD OR ROD LENSES 470
34.2.5 AXIAL GRIN MEDIA 472
34.2.6 SEIDEL ABERRATIONS OFA GRIN LENS WITH ROTATIONAL SYMMETRY 475
34.2.7 SEIDEL ABERRATIONS OF RADIAL GRIN MEDIA 476 34.2.8 SEIDEL
ABERRATIONS OF AXIAL GRIN MEDIA 477 34.2.9 ABERRATIONS OF RADIAL GRIN
MEDIA 478 34.2.10 ABERRATIONS OF AXIAL GRIN LENSES 481
34.2.11 GRADIUM MEDIA 482 34.2.12 EXAMPLES OF RADIAL AND AXIAL GRADIENT
SYSTEMS 485 34.2.13 EXAMPLES OF GRADIUM SYSTEMS 487 34.2.14 CHROMATIC
ABERRATIONS 489 34.2.15 PRINCIPLES FOR CORRECTION OF GRIN SYSTEMS 491
34.2.16 CORRECTION WITH GRADIUM LENSES 493 34.2.17 GENERAL APPLICATION
ASPECTS OF GRIN LENSES 495 34.3 SYSTEMS WITH DIFFRACTIVE ELEMENTS 495
34.3.1 INTRODUCTION 495
34.3.2 WORKING PRINCIPLE OF DIFFRACTIVE ELEMENTS 496 34.3.3 TYPES OF
DIFFRACTIVE ELEMENT 499 34.3.4 EQUIVALENT ASPHERICAL PHASE MASK 500
34.3.5 SWEATT MODEL 502
34.3.6 DISPERSION 502
34.3.7 FRESNEL ZONE LENS 503
34.3.8 ACHROMATIC HYBRID LENS 505 34.3.9 MULTI-ORDER DIFFRACTIVE LENSES
509 34.3.10 SEIDEL ABERRATIONS 511 34.3.11 DIFFRACTIVE SINGLET 513
34.3.12 DIFFRACTION EFFICIENCY 519 34.3.13 DIFFRACTIVE OPTICS FOR BROAD
SPECTRAL RANGES 522
34.3.14 ATHERMALIZATION WITH DIFFRACTIVE ELEMENTS 528 34.3.15 TRANSITION
BETWEEN REFRACTIVE AND DIFFRACTIVE SURFACES 529 34.3.16 OPTICAL DESIGN
WITH DIFFRACTIVE ELEMENTS 532 34.3.17 PRACTICAL ASPECTS AND TOLERANCES
533
34.3.18 APPLICATIONS 538 34.3.19 FURTHER EXAMPLES 539 34.4
NON-AXISYMMETRICAL SYSTEMS 543 34.4.1 INTRODUCTION 543
34.4.2 AXIS RAY AND 3D GEOMETRY 546 34.4.3 IMAGE TILT AND ANAMORPHISM
549 34.4.4 SECOND-ORDER ENVIRONMENTAL PROPAGATION AROUND THE AXIS RAY
552 34.4.5 VECTOR ABERRATION THEORY OF TILTED AXISYMMETRICAL COMPONENTS
555
34.4.6 THIRD-ORDER ABERRATIONS FOR TILTED COMPONENT SYSTEMS 558 34.4.7
GENERAL DISTORTION 562
IMAGE 9
XVI CONTENTS
34.4.8 GENERALIZED ABERRATION THEORY FOR PLANE SYMMETRIE SYSTEMS 563
34.4.9 SYSTEMS WITH GENERAL 3D GEOMETRY 564 34.4.10 EXAMPLES OF
ANAMORPHOTIC SYSTEMS 566 34.4.11 SCHIEFSPIEGIER TELESCOPES 571 34.4.12
EXAMPLE OF A GENERAL 3D SYSTEM 579 34.4.13 EXAMPLE WITH REFRACTIVE
COMPONENT 584 34.5 LITERATURE 587
35 TOLERANCING 595
35.1 INTRODUCTION 597
35.2 TOLERANCES FOR OPTICAL ELEMENTS AND OPTICAL SYSTEMS 600 35.2.1
INTRODUCTION TO TOLERANCES IN THE INTERNATIONAL STANDARD ISO-10110 600
35.2.2 STRESS BIREFRINGENCE 601
35.2.3 BUBBLES AND INCLUSIONS 603
35.2.4 INHOMOGENEITY AND STRIAE 602
35.2.5 SURFACE-FORM TOLERANCES 605 35.2.6 SPATIAL FREQUENCIES OF SURFACE
ERRORS 610 35.2.7 SURFACE-FORM TOLERANCES FOR ASPHERICAL SURFACES 613
35.2.8 SURFACE IMPERFECTION TOLERANCES 615
35.2.9 SURFACE TEXTURE 618
35.2.10 CENTERING TOLERANCES 630 35.3 DECENTER AND TILT TOLERANCES 631
35.3.1 CENTERING OF LENSES WITH SPHERICAL SURFACES 632 35.3.2 CENTERING
ERRORS IN ASPHERICAL LENSES 636 35.3.3 TYPICAL TYPES OF CENTERING ERRORS
IN PRACTICAL TOLERANCING 637 35.3.4 CONTROL OF CENTERING ERRORS IN
BONDING PROCESSES 639
35.3.5 CENTERING ERRORS OF LENSES IN MOUNTS 640 35.4 TOLERANCE COSTS 650
35.5 TOLERANCES, COMPENSATORS AND ADJUSTMENT 652 35.5.1 COMPENSATORS FOR
TYPICAL ABERRATIONS 653 35.5.2 MODELING OF ADJUSTMENT 657 35.5.3
EXAMPLE: ADJUSTMENT OF SPHERICAL ABERRATION, ON-AXIS ASTIGMATISM
AND ON-AXIS COMA 660 35.6 TOLERANCE DISTRIBUTIONS 667
35.7 PRACTICAL TOLERANCING 671
35.7.1 ASSIGNING TOLERANCES BY SENSITIVITY ANALYSIS 671 35.7.2
SENSITIVITY ANALYSIS 672 35.7.3 STATISTICAL SIMULATIONS 677 35.7.4
INVERSE TOLERANCING 685
35.8 PRISM TOLERANCES 690
35.8.1 INTRODUCTION 690
35.8.2 ANGLE ERRORS OF PRISMS IN THE PRINCIPAL PLANE 693 35.8.3
PRINCIPAL ANGLE ERRORS OF SPECIAL PRISMS 693 35.8.4 PYRAMIDAL ERROR 698
35.8.5 PYRAMIDAL ERRORS IN SPECIAL PRISMS 701
IMAGE 10
CONTENTS XVII
35.8.6 CALCULATION OF IMAGE ROTATION 70 35.8.7 ERROR IN THE ORIENTATION
OFA PRISM 706 35.8.8 ROOF-ANGLE TOLERANCES 706 35.8.9 ANGLE ERRORS IN A
CORNER CUBE PRISM 710 35.8.10 ASTIGMATISM TOLERANCE OF PRISMS 712 35.9
LITERATURE 714
A2 OPTICAL DESIGN SOFTWARE OPTALIX 717 A2.1 INTRODUCTION 718
A2.2 PROGRAM USER INTERFACE 718
A2.2.1 COMMAND LINE 719
A2.2.2 FUNCTIONS AND ARITHMETIC EXPRESSIONS 721 A2.2.3 LENS DATABASE
ITEMS 721
A2.3 CONFIGURATION AND SYSTEM DATA 722
A2.3.1 FIELDS 722
A2.3.2 WAVELENGTHS 723
A2.3.3 APERTURES 724
A2.4 SURFACE DATA 724
A2.4.1 SURFACE EDITOR 725
A2.4.2 SURFACE TYPES 726
A2.4.3 SURFACE APERTURES 728
A2.5 WORKED EXAMPLES 731
A2.5.1 TILTED SURFACES EXAMPLE 731 A2.5.2 ASPHERICAL SURFACES EXAMPLE
733 A2.5.3 ZOOM EXAMPLE 734
A2.5.4 GLOBAL SURFACE REFERENCES 737 A2.6 OPTICAL DESIGN IMPORT AND
EXPORT 739
A2.7 OPTALIX-PRO CAPABILITIES 742
A2.8 OBTAINING OPTALIX-LT 747
INDEX 749 |
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| id | DE-604.BV022226584 |
| illustrated | Illustrated |
| index_date | 2024-07-02T16:31:08Z |
| indexdate | 2024-07-09T20:52:49Z |
| institution | BVB |
| isbn | 9783527403790 3527403795 |
| language | English |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-015437725 |
| oclc_num | 634840535 |
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| owner_facet | DE-210 DE-355 DE-BY-UBR DE-1043 DE-706 DE-703 DE-573 DE-92 DE-634 DE-11 DE-M347 DE-526 DE-522 DE-19 DE-BY-UBM |
| physical | XXIII, 756 S. zahlr. graph. Darst 25 cm |
| publishDate | 2007 |
| publishDateSearch | 2007 |
| publishDateSort | 2007 |
| publisher | Wiley-VCH |
| record_format | marc |
| spelling | Handbook of optical systems 3 Aberration theory and correction of optical systems ed. by Herbert Gross Weinheim Wiley-VCH 2007 XXIII, 756 S. zahlr. graph. Darst 25 cm txt rdacontent n rdamedia nc rdacarrier Abbildungsfehler (DE-588)4132894-2 gnd rswk-swf Korrektur (DE-588)4205358-4 gnd rswk-swf Optisches System (DE-588)4126186-0 gnd rswk-swf Abbildungsfehler (DE-588)4132894-2 s Optisches System (DE-588)4126186-0 s Korrektur (DE-588)4205358-4 s DE-604 Gross, Herbert 1955- Sonstige (DE-588)134121201 oth (DE-604)BV019743683 3 GBV Datenaustausch application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=015437725&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis |
| spellingShingle | Handbook of optical systems Abbildungsfehler (DE-588)4132894-2 gnd Korrektur (DE-588)4205358-4 gnd Optisches System (DE-588)4126186-0 gnd |
| subject_GND | (DE-588)4132894-2 (DE-588)4205358-4 (DE-588)4126186-0 |
| title | Handbook of optical systems |
| title_auth | Handbook of optical systems |
| title_exact_search | Handbook of optical systems |
| title_exact_search_txtP | Handbook of optical systems |
| title_full | Handbook of optical systems 3 Aberration theory and correction of optical systems ed. by Herbert Gross |
| title_fullStr | Handbook of optical systems 3 Aberration theory and correction of optical systems ed. by Herbert Gross |
| title_full_unstemmed | Handbook of optical systems 3 Aberration theory and correction of optical systems ed. by Herbert Gross |
| title_short | Handbook of optical systems |
| title_sort | handbook of optical systems aberration theory and correction of optical systems |
| topic | Abbildungsfehler (DE-588)4132894-2 gnd Korrektur (DE-588)4205358-4 gnd Optisches System (DE-588)4126186-0 gnd |
| topic_facet | Abbildungsfehler Korrektur Optisches System |
| url | http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=015437725&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA |
| volume_link | (DE-604)BV019743683 |
| work_keys_str_mv | AT grossherbert handbookofopticalsystems3 |