| Preface |
|
xv | |
| Colour Plates |
|
xix | |
|
|
|
1 | (8) |
|
|
|
1 | (1) |
|
A brief historical background |
|
|
2 | (1) |
|
The scope of the present book |
|
|
3 | (1) |
|
Overview of the following chapters |
|
|
4 | (3) |
|
About the exercises and the moire demonstration samples |
|
|
7 | (2) |
|
Background and basic notions |
|
|
9 | (50) |
|
|
|
9 | (1) |
|
The spectral approach; images and their spectra |
|
|
10 | (5) |
|
Superposition of two cosinusoidal gratings |
|
|
15 | (3) |
|
Superposition of three or more cosinusoidal gratings |
|
|
18 | (3) |
|
Binary square waves and their spectra |
|
|
21 | (2) |
|
Superposition of binary gratings; higher order moires |
|
|
23 | (7) |
|
The impulse indexing notation |
|
|
30 | (3) |
|
The notational system for superposition moires |
|
|
33 | (2) |
|
Singular moire states; stable vs. unstable moire-free superpositions |
|
|
35 | (3) |
|
The intensity profile of the moire and its perceptual contract |
|
|
38 | (2) |
|
Square grids and their superpositions |
|
|
40 | (4) |
|
Dot-screens and their superpositions |
|
|
44 | (4) |
|
Sampling moires; moires as aliasing phenomena |
|
|
48 | (3) |
|
Advantages of the spectral approach |
|
|
51 | (8) |
|
|
|
52 | (7) |
|
|
|
59 | (22) |
|
|
|
59 | (1) |
|
Colour separation and halftoning |
|
|
60 | (2) |
|
The challenge of moire minimization in colour printing |
|
|
62 | (2) |
|
Navigation in the moire parameter space |
|
|
64 | (7) |
|
The case of two superposed screens |
|
|
65 | (3) |
|
The case of three superposed screens |
|
|
68 | (3) |
|
Finding moire-free screen combinations for colour printing |
|
|
71 | (4) |
|
|
|
75 | (6) |
|
|
|
77 | (4) |
|
The moire profile form and intensity levels |
|
|
81 | (28) |
|
|
|
81 | (1) |
|
Extraction of the profile of a moire between superposed line-gratings |
|
|
82 | (7) |
|
Extension of the moire extraction to the 2D case of superposed screens |
|
|
89 | (7) |
|
The special case of the (1,0,-1,0)-moire |
|
|
96 | (6) |
|
The forms of the moire cells |
|
|
97 | (4) |
|
The orientation of the moire cells |
|
|
101 | (1) |
|
The case of more complex and higher order moires |
|
|
102 | (7) |
|
|
|
103 | (6) |
|
The algebraic foundation of the spectrum properties |
|
|
109 | (40) |
|
|
|
109 | (1) |
|
The support of a spectrum; lattices and modules |
|
|
109 | (5) |
|
Lattices and modules in Rn |
|
|
110 | (3) |
|
Application to the frequency spectrum |
|
|
113 | (1) |
|
The mapping between the impulse indices and their geometric locations |
|
|
114 | (1) |
|
A short reminder from linear algebra |
|
|
115 | (3) |
|
The image and the kernel of a linear transformation |
|
|
115 | (1) |
|
Partition of a vector space into equivalence classes |
|
|
116 | (1) |
|
The partition of V into equivalence classes induced by Φ |
|
|
117 | (1) |
|
The application of these results to our continuous case |
|
|
118 | (1) |
|
The discrete mapping &Psi vs. the continuous mapping Φ |
|
|
118 | (3) |
|
The algebraic interpretation of the impulse locations in the spectrum support |
|
|
121 | (5) |
|
The global spectrum support |
|
|
121 | (2) |
|
The individual impulse-clusters |
|
|
123 | (2) |
|
The spread-out clusters slightly off the singular state |
|
|
125 | (1) |
|
|
|
126 | (17) |
|
|
|
143 | (6) |
|
|
|
146 | (3) |
|
Fourier-based interpretation of the algebraic spectrum properties |
|
|
149 | (16) |
|
|
|
149 | (1) |
|
Image domain interpretation of the algebraic structure of the spectrum support |
|
|
149 | (2) |
|
Image domain interpretation of the impulse-clusters in the spectrum |
|
|
151 | (1) |
|
The amplitude of the collapsed impulse-clusters in a singular state |
|
|
152 | (1) |
|
The exponential Fourier expression for two-grating superpositions |
|
|
153 | (2) |
|
Two-grating superpositions and their singular states |
|
|
155 | (3) |
|
Two gratings with identical frequencies |
|
|
155 | (2) |
|
Two gratings with different frequencies |
|
|
157 | (1) |
|
Two-screen superpositions and their singular states |
|
|
158 | (3) |
|
The general superposition of m layers and its singular states |
|
|
161 | (4) |
|
|
|
163 | (2) |
|
|
|
165 | (26) |
|
|
|
165 | (1) |
|
The phase of a periodic function |
|
|
166 | (2) |
|
The phase terminology for periodic functions in the 1D case |
|
|
168 | (1) |
|
The phase terminology for 1-fold periodic functions in the 2D case |
|
|
169 | (2) |
|
The phase terminology for the general 2D case: 2-fold periodic functions |
|
|
171 | (5) |
|
Using the period-vector notation |
|
|
172 | (1) |
|
Using the step-vector notation |
|
|
173 | (3) |
|
Moire phases in the superposition of periodic layers |
|
|
176 | (3) |
|
The influence of layer shifts on the overall superposition |
|
|
179 | (12) |
|
|
|
186 | (5) |
|
Macro- and microstructures in the superposition |
|
|
191 | (42) |
|
|
|
191 | (3) |
|
Rosettes in singular states |
|
|
194 | (4) |
|
Rosettes in periodic singular states |
|
|
194 | (1) |
|
Rosettes in almost-periodic singular states |
|
|
195 | (3) |
|
The influence of layer shifts on the rosettes in singular states |
|
|
198 | (2) |
|
The microstructure slightly off the singular state; the relationship between macro- and microstructures |
|
|
200 | (1) |
|
The microstructure in stable moire-free superpositions |
|
|
201 | (3) |
|
Rational vs. irrational screen superpositions; rational approximants |
|
|
204 | (6) |
|
|
|
210 | (8) |
|
The microstructure of the conventional 3-screen superposition |
|
|
218 | (5) |
|
Variance or invariance of the microstructure under layer shifts |
|
|
223 | (3) |
|
Period-coordinates and period-shifts in the Fourier decomposition |
|
|
226 | (7) |
|
|
|
231 | (2) |
|
Polychromatic moire effects |
|
|
233 | (16) |
|
|
|
233 | (1) |
|
Some basic notions from colour theory |
|
|
234 | (2) |
|
Physical aspects of colour |
|
|
234 | (1) |
|
Physiological aspects of colour |
|
|
235 | (1) |
|
Extension of the spectral approach to the polychromatic case |
|
|
236 | (5) |
|
The representation of images and image superpositions |
|
|
236 | (4) |
|
The influence of the human visual system |
|
|
240 | (1) |
|
The Fourier-spectrum convolution and the superposition moires |
|
|
241 | (1) |
|
Extraction of the moire intensity profiles |
|
|
241 | (1) |
|
The (1,-1)-moire between two colour line-gratings |
|
|
242 | (3) |
|
The (1,0,-1,0)-moire between two colour dot-screens |
|
|
245 | (1) |
|
The case of more complex and higher-order moires |
|
|
246 | (3) |
|
|
|
246 | (3) |
|
Moires between repetitive, non-periodic layers |
|
|
249 | (104) |
|
|
|
249 | (1) |
|
Repetitive, non-periodic layers |
|
|
250 | (8) |
|
The influence of a coordinate change on the spectrum |
|
|
258 | (6) |
|
Curvilinear cosinusoidal gratings and their different types of spectra |
|
|
264 | (8) |
|
Gradual transitions between cosinusoidal gratings of different types |
|
|
268 | (4) |
|
The Fourier decomposition of curved, repetitive structures |
|
|
272 | (3) |
|
The Fourier decomposition of curvilinear gratings |
|
|
272 | (2) |
|
The Fourier decomposition of curved line-grids and dot-screens |
|
|
274 | (1) |
|
The spectrum of curved, repetitive structures |
|
|
275 | (4) |
|
The spectrum of curvilinear gratings |
|
|
275 | (3) |
|
The spectrum of curved line-grids and dot-screens |
|
|
278 | (1) |
|
The superposition of curved, repetitive layers |
|
|
279 | (44) |
|
Moires in the superposition of curved, repetitive layers |
|
|
279 | (3) |
|
Image domain vs. spectral domain investigation of the superposition |
|
|
282 | (1) |
|
The superposition of a parabolic grating and a periodic straight grating |
|
|
283 | (7) |
|
The superposition of two parabolic gratings |
|
|
290 | (7) |
|
The superposition of a circular grating and a periodic straight grating |
|
|
297 | (9) |
|
The superposition of two circular gratings |
|
|
306 | (5) |
|
The superposition of a zone grating and a periodic straight grating |
|
|
311 | (8) |
|
The superposition of two circular zone gratings |
|
|
319 | (4) |
|
Periodic moires in the superposition of non-periodic layers |
|
|
323 | (6) |
|
Moire analysis and synthesis in the superpositions of curved, repetitive layers |
|
|
329 | (14) |
|
The case of curvilinear gratings |
|
|
329 | (8) |
|
The case of curved dot-screens |
|
|
337 | (6) |
|
Local frequencies and singular states in curved, repetitive cases |
|
|
343 | (4) |
|
Moires in the superposition of screen gradations |
|
|
347 | (1) |
|
|
|
348 | (5) |
|
|
|
349 | (4) |
|
Other possible approaches for moire analysis |
|
|
353 | (96) |
|
|
|
353 | (1) |
|
The indicial equations method |
|
|
353 | (7) |
|
|
|
358 | (1) |
|
Comparison with the spectral approach |
|
|
359 | (1) |
|
Approximation using the first harmonic |
|
|
360 | (3) |
|
|
|
362 | (1) |
|
The local frequency method |
|
|
363 | (6) |
|
|
|
368 | (1) |
|
Comparison with the spectral approach |
|
|
369 | (1) |
|
|
|
369 | (6) |
|
|
|
370 | (5) |
| Appendices |
|
|
A. Periodic functions and their spectra |
|
|
375 | (20) |
|
|
|
375 | (1) |
|
A.2 Periodic functions, their Fourier series and their spectra in the 1D case |
|
|
375 | (3) |
|
A.3 Periodic functions, their Fourier series and their spectra in the 2D case |
|
|
378 | (1) |
|
A.3.1 1-fold periodic functions in the x or y direction |
|
|
378 | (1) |
|
A.3.2 2-fold periodic functions in the x and y directions |
|
|
378 | (2) |
|
A.3.3 1-fold periodic functions in an arbitrary direction |
|
|
380 | (1) |
|
A.3.4 2-fold periodic functions in arbitrary directions (skew-periodic functions) |
|
|
381 | (5) |
|
A.4 The period-lattice and the frequency-lattice (=spectrum support) |
|
|
386 | (3) |
|
A.5 The matrix notation, its appeal, and its limitations for our needs |
|
|
389 | (3) |
|
A.6 The period-vectors Pi vs. the step-vectors Ti |
|
|
392 | (3) |
|
B. Almost-periodic functions and their spectra |
|
|
395 | (14) |
|
|
|
395 | (1) |
|
B.2 A simple illustrative example |
|
|
395 | (1) |
|
B.3 Definitions and main properties |
|
|
396 | (3) |
|
B.4 The spectrum of almost-periodic functions |
|
|
399 | (2) |
|
B.5 The different classes of almost-periodic functions and their spectra |
|
|
401 | (3) |
|
B.6 Characterization of functions according to their spectrum support |
|
|
404 | (2) |
|
B.7 Almost-periodic functions in two variables |
|
|
406 | (3) |
|
C. Miscellaneous issues and derivations |
|
|
409 | (24) |
|
C.1 Derivation of the classical moire formula (2.9) of Sec. 2.4 |
|
|
409 | (1) |
|
C.2 Derivation of the first part of Proposition 2.1 of Sec. 2.5 |
|
|
410 | (1) |
|
C.3 Invariance of the impulse amplitudes under rotations and x,y scalings |
|
|
411 | (1) |
|
C.3.1 Invariance of the 2D Fourier transform under rotations |
|
|
411 | (1) |
|
C.3.2 Invariance of the impulse amplitudes under x,y scalings |
|
|
411 | (1) |
|
|
|
412 | (1) |
|
|
|
412 | (2) |
|
C.4.2 The particular case of periodic functions |
|
|
414 | (1) |
|
C.4.3 The phase of a periodic function: the φ and the φ notations |
|
|
415 | (2) |
|
C.5 The function RC(u) converges to δ(u) as a-->0 |
|
|
417 | (1) |
|
C.6 The 2D spectrum of a cosinusoidal zone grating |
|
|
418 | (1) |
|
C.7 The convolution of two orthogonal line-impulses |
|
|
419 | (1) |
|
C.8 The compound line-impulse of the singular (k1,k2)-line-impulse cluster |
|
|
420 | (3) |
|
C.9 The 1D Fourier transform of the chirp cos(ax2 + b) |
|
|
423 | (1) |
|
C.10 The 2D Fourier transform of the 2D chirp cos(ax2 + by2 + c) |
|
|
424 | (1) |
|
C.11 The spectrum of screen gradations |
|
|
425 | (4) |
|
C.12 Convergence issues related to Fourier series |
|
|
429 | (1) |
|
C.12.1 On the convergence of Fourier series |
|
|
429 | (1) |
|
C.12.2 Multiplication of infinite series |
|
|
430 | (2) |
|
C.13 Moire effects in image reproduction |
|
|
432 | (1) |
|
D. Glossary of the main terms |
|
|
433 | (16) |
|
|
|
433 | (1) |
|
D.2 Terms in the image domain |
|
|
434 | (4) |
|
D.3 Terms in the spectral domain |
|
|
438 | (4) |
|
D.4 Terms related to moire |
|
|
442 | (2) |
|
D.5 Terms related to light and colour |
|
|
444 | (2) |
|
|
|
446 | (3) |
| List of notations and symbols |
|
449 | (4) |
| List of abbreviations |
|
453 | (2) |
| References |
|
455 | (10) |
| Index |
|
465 | |
Lisainfo e-raamatute kohta