Atnaujinkite slapukų nuostatas

Industrial Color Physics [Kietas viršelis]

4.00/5 (1 ratings by Goodreads)
  • Formatas: Hardback, 509 pages, aukštis x plotis: 235x155 mm, weight: 1041 g, 52 Tables, black and white; 19 Illustrations, color; 191 Illustrations, black and white; XIV, 509 p. 210 illus., 19 illus. in color., 1 Hardback
  • Serija: Springer Series in Optical Sciences 154
  • Išleidimo metai: 18-May-2010
  • Leidėjas: Springer-Verlag New York Inc.
  • ISBN-10: 1441911960
  • ISBN-13: 9781441911964
Kitos knygos pagal šią temą:
Industrial Color PhysicsDidesnis paveikslėlis
  • Formatas: Hardback, 509 pages, aukštis x plotis: 235x155 mm, weight: 1041 g, 52 Tables, black and white; 19 Illustrations, color; 191 Illustrations, black and white; XIV, 509 p. 210 illus., 19 illus. in color., 1 Hardback
  • Serija: Springer Series in Optical Sciences 154
  • Išleidimo metai: 18-May-2010
  • Leidėjas: Springer-Verlag New York Inc.
  • ISBN-10: 1441911960
  • ISBN-13: 9781441911964
Kitos knygos pagal šią temą:
Pastovi nuoroda: https://www.kriso.lt/db/9781441911964.html
Raktažodžiai:
Colors arise only in the brain, normally originating from electromagnetic waves from the outside world. This book is based on courses given by the author in the Department of Colors, Paints and Plastics at the University of Applied Sciences in Stuttgart and continued at the University of Applied Sciences in Esslingen, Germany. The development of color physics in industry began in the middle of the 19th century with the large-scale manufacturing of natural colors. Since that time, a great variety of new, especially synthetic, colorants have been produced in order to meet increasing demands for non-self-luminous colors with regard to color applications. The rapid progress in color physics and accompanying applications over the last three decades are the reasons for this work. Here, the fundamentals of color physics are outlined and the most important recent developments and applications in the color industry are discussed. 1 In comparison to the ?rst German edition, all chapters of the book have been revised and expanded with regard to effect pigments. After the introd- tory chapter, the optical fundamentals of absorbing and effect colorants are discussed. The exceptional spectral and colorimetric properties of effect p- ments are detailed in combination with further characterizing parameters. Color spaces are presented as well as the ef ciency of recent color difference f- mulas. In addition to the normal spectral measuring methods for absorbing colorants, modi ed procedures for effect colorations are outlined.
1 Introduction
1(10)
References
8(3)
2 Light Sources, Types of Colorants, Observer
11(122)
2.1 Optical Radiation Sources and Interactions of Light
11(32)
2.1.1 Visible Spectrum and Colors
12(2)
2.1.2 Types of Light Sources
14(4)
2.1.3 Technical Light Sources
18(5)
2.1.4 Illuminants
23(2)
2.1.5 Geometric Optical Interactions
25(9)
2.1.6 Interference of Light
34(4)
2.1.7 Diffraction from Transmission and Reflection Gratings
38(5)
2.2 Absorbing Colorants
43(20)
2.2.1 Types and Attributes of Absorbing Colorants
43(5)
2.2.2 Pigment Mixtures and Light Transmittance
48(3)
2.2.3 Description of Color Attributes
51(6)
2.2.4 Color-Order Systems
57(2)
2.2.5 Surface Phenomenon
59(4)
2.3 Effect Pigments
63(46)
2.3.1 Types of Metallic Pigments
65(4)
2.3.2 Morphology of Metallic Particles
69(7)
2.3.3 Coloristic Properties of Metallic Pigments
76(6)
2.3.4 Sorts of Pearlescent and Interference Colorants
82(3)
2.3.5 Interference Pigments Consisting of Multiple Layers
85(6)
2.3.6 Spectral Behavior of Pearlescent and Interference Colorants
91(10)
2.3.7 Opaque Films Containing Absorbing and Effect Pigments
101(3)
2.3.8 Colors of Diffraction Pigments
104(5)
2.4 Observer
109(24)
2.4.1 Color Perception and Color Theories
110(4)
2.4.2 Color Perception Phenomenon
114(2)
2.4.3 Subtractive and Additive Mixing of Colors
116(4)
2.4.4 Tristimulus Color-Matching Experiments
120(3)
2.4.5 Determination of Tristimulus Values
123(2)
2.4.6 CIE 1931 and CIE 1964 Standard Colorimetric Observers
125(4)
References
129(4)
3 Systems of Standardized Tristimulus Values, Color Qualities, Chroma of Effect Pigments
133(100)
3.1 Systems of Standardized Tristimulus Values
133(19)
3.1.1 CIE 1931 Tristimulus Values
134(3)
3.1.2 Chromaticity Coordinates and Chromaticity Diagram
137(4)
3.1.3 CIE 1976 Color Spaces
141(7)
3.1.4 DIN99o Color Space
148(4)
3.2 Color Difference Metrics and Color Tolerances
152(12)
3.2.1 CMC (l: c) Color Difference Formula
153(1)
3.2.2 CIE94 Color Difference Expression
154(3)
3.2.3 CIEDE2000 Color Difference Equation
157(2)
3.2.4 Efficiency of Color Difference Formulas, CIE Color Appearance Models
159(2)
3.2.5 Color Tolerances
161(3)
3.3 Color Constancy and Metamerism
164(11)
3.3.1 Chromatic Adaptation and Color Constancy
164(2)
3.3.2 Index of Color Inconstancy
166(3)
3.3.3 Kinds of Metamerism
169(3)
3.3.4 Special Metamerism Indices
172(3)
3.4 Specific Qualities of Colorants
175(25)
3.4.1 Build-up and Coloring Potential
176(3)
3.4.2 Strength and Depth of Color
179(6)
3.4.3 Covering Capacity
185(4)
3.4.4 Transparency and Coloring Power
189(3)
3.4.5 Color Fastness and Turbidity
192(5)
3.4.6 Stability of Effect Pigments
197(3)
3.5 Chroma of Effect Pigments
200(33)
3.5.1 Coloristic Quantities of Effect Pigments
201(5)
3.5.2 Color Difference Equation for Metallics
206(3)
3.5.3 Chroma of Pearlesence and Interference Pigments
209(5)
3.5.4 Mixtures of Effect Pigments
214(7)
3.5.5 Color Development of Diffraction Pigments
221(7)
References
228(5)
4 Measuring Colors
233(62)
4.1 Measurement of Reflecting and Transmitting Materials
234(23)
4.1.1 Measurement of Colors and Visual Judgment
235(4)
4.1.2 Measurement Geometries
239(9)
4.1.3 Sample Requirements
248(2)
4.1.4 Transparent, Translucent, Opaque Colors
250(2)
4.1.5 Color Matching
252(3)
4.1.6 Acceptability and Tolerance Agreement
255(2)
4.2 Measuring Methods
257(21)
4.2.1 Tristimulus Colorimeter
257(2)
4.2.2 Spectrophotometer
259(4)
4.2.3 Accuracy of Spectrophotometers
263(3)
4.2.4 Reflectance and Transmittance of Layers
266(5)
4.2.5 Auxiliary Optical Methods for Effect Pigments
271(3)
4.2.6 Fluorescent, Thermochromic, Photochromic Colors
274(4)
4.3 Uncertainties of Spectral Color Measurement
278(17)
4.3.1 Qualitative Errors
279(1)
4.3.2 Quantitative Errors and Error Distribution
280(4)
4.3.3 Normal Distribution in Three and More Dimensions
284(3)
4.3.4 Statistical Testing of Color Differences
287(5)
References
292(3)
5 Theories of Radiative Transfer
295(86)
5.1 Fundamentals
295(21)
5.1.1 Basic Concepts and Definitions
296(3)
5.1.2 Absorption and Scattering
299(3)
5.1.3 Single and Multiple Scattering
302(4)
5.1.4 Radiative Transfer Equation
306(2)
5.1.5 Radiative Transfer in Plane Parallel Layers
308(5)
5.1.6 Phase Function for Anisotropic Scattering
313(3)
5.2 Directional Two-Flux Approximation
316(10)
5.2.1 Reflection and Transmission
317(2)
5.2.2 Optical Special Cases
319(2)
5.2.3 Optical Triangle
321(3)
5.2.4 Determination of Optical Coefficients
324(2)
5.3 Theory of Kubelka and Munk
326(14)
5.3.1 Empirical Approach
327(2)
5.3.2 Exceptional Optical Cases
329(2)
5.3.3 Determination of Optical Constants
331(1)
5.3.4 Boundary Layer Correction
332(5)
5.3.5 Limits of Kubelka-Munk Theory
337(3)
5.4 Three-Flux Approximation
340(16)
5.4.1 Conception of Three-Flux Theory
341(2)
5.4.2 Reflection and Transmission
343(2)
5.4.3 Optically Different Materials
345(3)
5.4.4 Correction of Surface Effects
348(4)
5.4.5 Special Cases of External Reflection and Transmission
352(4)
5.5 Approximation of Radiative Transfer by Multi-Flux Theory
356(25)
5.5.1 Exact Solutions for Internal Reflection and Transmission
357(6)
5.5.2 Surface Boundary Corrections
363(5)
5.5.3 Total Reflection and Optical Extreme Cases
368(2)
5.5.4 Boundary Conditions, Matrices of Reflection and Transmission
370(2)
5.5.5 Directional and Diffuse Reflection and Transmission
372(1)
5.5.6 Inclusion of Total Reflection
373(4)
5.5.7 Corrected Optical Triangle
377(2)
References
379(2)
6 Recipe Prediction
381(66)
6.1 Classical Method
382(21)
6.1.1 Calibration Series with Absorbing Colorants
384(6)
6.1.2 Calibration and Reference Colorations for Effect Pigments
390(3)
6.1.3 Determination of Absorption and Scattering Coefficients
393(4)
6.1.4 Optical Path and Albedo
397(2)
6.1.5 Coefficients of the Phase Function
399(1)
6.1.6 Accuracy of Predicted Recipes
400(3)
6.2 Strategies for Recipe Prediction
403(17)
6.2.1 Numerical Methods
404(5)
6.2.2 Spectrometric Strategy
409(5)
6.2.3 Colorimetric Method
414(3)
6.2.4 Balanced Color Differences
417(3)
6.3 Realization of Recipes
420(27)
6.3.1 Selection of Suitable Recipes
421(3)
6.3.2 Sensitivity and Correctability of Color Recipes
424(3)
6.3.3 Numerical Procedures for Recipe Correction
427(4)
6.3.4 Databases
431(4)
6.3.5 Modified Expert Systems
435(6)
6.3.6 Neural Networks
441(4)
References
445(2)
Appendix
447(8)
A.1 Non-colored Applications of Effect Pigments
447(1)
A.1.1 Metallic Pigments
447(1)
A.1.2 Pearlcscent Pigments
448(1)
A.2 Chromatic Adaption Transform CAT02
448(3)
A.2.1 Forward Mode
448(2)
A.2.2 Reverse Mode
450(1)
A.3 Two-Flux Approximations
451(4)
A.3.1 Directional Fluxes
451(2)
A.3.2 Diffuse Fluxes
453(2)
References in Alphabetic Order 455(12)
Name Index 467(2)
Index 469
The author, Georg A. Klein, studied physics, solid state physics, and polymer physics at Universities in Goettingen, Saarbruecken, and Mainz, Germany. He was awarded his Ph. D. in polymer physics from the University of Mainz, Germany. After several years of R&D in the chemical industry, he became a professor for physics, color physics, and technology of polymers at the University of Applied Sciences in Stuttgart. His extensive decades-long experience in color physics and color technology in Germany and abroad is condensed in the present book.