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Journal of Coatings Technology and Research

Erschienen in:

28.03.2018

Mathematical and empirical evaluation of accuracy of the Kubelka–Munk model for color match prediction of opaque and translucent surface coatings

verfasst von: M. Gorji Bandpay, F. Ameri, K. Ansari, S. Moradian

Erschienen in: Journal of Coatings Technology and Research | Ausgabe 5/2018

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Abstract

Attempts were made to evaluate mathematically and empirically the accuracy of the Kubelka–Munk model for color match prediction of opaque and translucent surface coatings in the color using industries. To this end, an innovative inversed mathematical evaluation procedure was concocted which comprised of plotting the absorption and scattering constants of the Kubelka–Munk model or any of its various modified form or replacements theories against the intrinsic optical coefficients of the respective exact radiation transfer theories, namely Chandrasekhar for opaque and van de Hulst for translucent media. The results prove mathematically that the Kubelka–Munk model for opaque media is a sound theory and its various suggested modifications or replacements do not improve the color match prediction of opaque surface coating media. This mathematical conclusion was further confirmed by color match prediction of actual opaque paint samples. On the other hand, the mathematical prediction for translucent media illustrated a completely different picture, depicting nonlinearity between the optical constants and the respective concentrations of colorants. This implies that much further work has to be carried out to derive invertible new equations to enforce linearity to such situations or make use of alternative artificial intelligent procedures which are designed especially for nonlinearity.

Vorheriger Artikel Improved corrosion resistance based on APTES-grafted reduced sulfonated graphene/waterborne polyurethane coatings

Nächster Artikel Sonochemically sol–gel derived coating of textiles using heterojunction SnO2/ZnO/chitosan bionanocomposites: in vitro antibacterial evaluation

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Schuster, A, “Radiation Through a Foggy Atmosphere.” Astrophys. J., 21 1 (1905)CrossRef

Kubelka, P, Munk, F, “An Article on Optics of Paint Layers.” Z. Tech. Phys., 12 (1930) 593–601 (1931)

Berns, RS, Mohammadi, M, “Single-Constant Simplification of Kubelka–Munk Turbid-Media Theory for Paint Systems: A Review.” Color Res. Appl., 32 (3) 201–207 (2007)CrossRef

Zhao, Y, Berns, RS, “Predicting the Spectral Reflectance Factor of Translucent Paints Using Kubelka–Munk Turbid Media Theory: Review and Evaluation.” Color Res. Appl., 34 (6) 417–431 (2009)CrossRef

Berns, RS, Mohammadi, M, “Evaluating Single- and Two-Constant Kubelka–Munk Turbid Media Theory for Instrumental-Based Inpainting.” Stud. Conserv., 52 (4) 299–314 (2007)CrossRef

Mahnaz, M and Berns, RS, “Verification of the Kubelka–Munk Turbid Media Theory for Artist Acrylic Paint.” Art-Si.Org, pp. 1–15 (2004)

Takagi, A, Sato, S, Baba, G, “Prediction of Spectral Reflectance Factor Distribution of Color-Shift Paint Finishes.” Color Res. Appl., 32 (5) 378–387 (2007)CrossRef

Takagi, A, Watanabe, A, Baba, G, “Prediction of Spectral Reflectance Factor Distribution of Automotive Paint Finishes.” Color Res. Appl., 30 (4) 275–282 (2005)CrossRef

Gunde, MKE, Logar, JKA, Orel, ZC, Orel, B, “Application of the Kubelka–Munk Model to Thickness-Dependent Diffuse Reflectance of Black Paints in the Mid-IR.” Appl. Spectrosc., 49 (5) 623–629 (1995)CrossRef

10.

Zhao, Y, Berns, RS, “Further investigations of colorant database development for two-constant Kubelka–Munk model for artist acrylic and oil paints’.” MCSL Technical Report, (2006)

11.

Mohammadi, M and Berns, RS, “Testing instrumental-based color matching for artist acrylic paints.” Tech. rep., Rochester Institute of Technology, College of Science, Munsell Color Science Laboratory, (2006)

12.

Hongying, Y, Sukang, Z, Ning, P, “On the Kubelka–Munk Single-Constant/Two-Constant Theories.” Text. Res. J., 80 (3) 263–270 (2010)CrossRef

13.

De Lucia, M and Buonopane, M, “Color Prediction in Textile Application.” Proceedings of SPIE—the International Society for Optical Engineering, 5457 678–688 (2004)

14.

Zhang, B, Li, H, “Research on Application for Color Matching in Textile Dyeing Based on Numerical Analysis.” International Conference on Computer Science and Software Engineering, pp. 357–360 (2008)

15.

Džimbeg-malčić, V, Barbarić-mikočević, Ž, Itrić, K, “Kubelka–Munk Model in Describing Optical Properties of Paper (I).” Tech. Gaz., 18 (1) 191–196 (2011)

16.

Džimbeg-malčić, V, Barbarić-mikočević, Ž, Itrić, K, “Kubelka–Munk Model in Describing Optical Properties of Paper (II).” Tech. Gaz., 19 (1) 191–196 (2012)

17.

Ma, T, Johnston, WM, Korn, A, “The Color Accuracy of the Kubelka–Munk Model for Various Colorants in Maxillofacial Prosthetic Material.” J. Dent. Res., 66 (9) 1438–1444 (1987)CrossRef

18.

Mikhail, SS, Azer, SS, Johnston, WM, “Accuracy of Kubelka–Munk Reflectance Theory for Dental Resin Composite Material.” Dent. Mater., 28 (7) 729–735 (2012)CrossRef

19.

Ragain, JC, Johnston, WM, “Accuracy of Kubelka–Munk Reflectance Theory Applied to Human Dentin and Enamel.” J. Dent. Res., 80 (2) 449–452 (2001)CrossRef

20.

Nobbs, JH, “Kubelka–Munk Model and the Prediction of Reflectance.” Rev. Prog. Color. Relat. Top., 15 (1) 66–75 (1985)CrossRef

21.

Vargas, WE, Niklasson, GA, “Applicability Conditions of the Kubelka–Munk Model.” Appl. Opt., 36 (22) 5580–5586 (1997)CrossRef

22.

Roy, A, Ramasubramaniam, R, Gaonkar, HA, “Empirical relationship between Kubelka-Munk and radiative transfer coefficients for extracting optical parameters of tissues in diffusive and nondiffusive regimes.” J. Biomed. Opt., 17 (11) 115006 (2012)CrossRef

23.

Yang, L, Miklavcic, SJ, “Revised Kubelka–Munk Model. III: A General Theory of Light Propagation in Scattering and Absorptive Media.” J. Opt. Soc. Am. A, 22 (9) 1866–1873 (2005)CrossRef

24.

Kokhanovsky, AA, “Physical Interpretation and Accuracy of the Kubelka–Munk Theory.” J. Phys. D: Appl. Phys, 40 2210–2216 (2007)CrossRef

25.

Duncan, DR, “The Colour of Pigment Mixtures.” Proc. Phys. Soc., 52 (3) 390–401 (1940)CrossRef

26.

Nickols, DG, Orchard, SE, “Precision of Determination of Kubelka and Munk Coefficients from Opaque Colorant Mixtures.” J. Opt. Soc. Am. A, 55 (2) 162–164 (1965)CrossRef

27.

Shah, HS, Billmeyer, FW, “Kubelka–Munk Analysis of Absorptance in the Presence of Scattering, Including Surface-Reflection Correction to Transmittance.” Color Res. Appl., 10 (1) 26–31 (1985)CrossRef

28.

Davidson, HR, Hemmendinger, H, Landry, JLR, “A System of Instrumental Colour Control for the Textile Industry.” J. Soc. Dye. Colour., 79 (12) 577–590 (2008)CrossRef

29.

Blevin, WR, Brown, WJ, “Light-Scattering Properties of Pigment Suspensions.” J. Opt. Soc. Am. A, 51 (9) 975–982 (1961)CrossRef

30.

Allen, E, Calculations for Colorant Formulations. ACS Publications, New York (1971)CrossRef

31.

Cheong, WFWF, Prahl, SAS, Welch, AJA, “A Review of the Optical Properties of Biological Tissues.” IEEE J. Quantum Electron., 26 (12) 2166–2185 (1990)CrossRef

32.

Valz, H, Industrial Color Testing: Fundamentals and Techniques. Wiley-VCH, New York (2001)CrossRef

33.

Yang, L, Kruse, B, “Revised Kubelka Munk Theory. I. Theory and Application.” J. Opt. Soc. Am. A, 21 (10) 1933–1941 (2004)CrossRef

34.

Pierce, PE, Marcus, RT, “Radiative Transfer Theory Solid Color-Matching Calculations.” Color Res. Appl., 22 (2) 72–87 (1997)CrossRef

35.

Kubelka, P, “New Contributions to the Optics of Intensely Light-Scattering Materials Part II: Nonhomogeneous Layers.” J. Opt. Soc. Am. A, 44 (4) 330–335 (1954)CrossRef

36.

Mudgett, PS, Richards, LW, “Multiple Scattering Calculations for Technology.” Appl. Opt., 10 (7) 1485–1502 (1971)CrossRef

37.

Kubelka, P, “New Contributions to the Optics of Intensely Light-Scattering Materials. Part I.” J. Opt. Soc. Am. A, 38 (5) 448–457 (1948)CrossRef

38.

Graaff, R, Aarnoudse, JG, de Mul, FF, Jentink, HW, “Light Propagation Parameters for Anisotropically Scattering Media Based on a Rigorous Solution of the Transport Equation.” Appl. Opt., 28 (12) 2273–2279 (1989)CrossRef

39.

De La Osa, RA, Alonso, AG, Ortiz, D, González, F, Moreno, F, Saiz, JM, “Extension of the Kubelka–Munk Theory to an Arbitrary Substrate: A Monte Carlo Approach.” J. Opt. Soc. Am. A, 33 (10) 2053–2060 (2016)CrossRef

40.

Reynolds, L, Johnson, C, Ishimaru, A, “Diffuse Reflectance from a Finite Blood Medium: Applications to the Modeling of Fiber Optic Catheters.” Appl. Opt., 15 (9) 2059–2067 (1976)CrossRef

41.

Giovanelli, R, “Reflection by Semi-Infinite Diffusers.” J. Modern. Opt., 2 (4) 153–162 (1955)

42.

Case, KM, Zweifel, PF, Linear Transport Theory. Addison-Wesley, Reading (1967)

43.

Chandrasekhar, S, Radiative Transfer. Dover Publications, New York (1960)

44.

de Hulst, V, Christoffel, H, Multiple Light Scattering: Tables, Formulas and Applications, Vol. 1. Academic Press, New York (1980)

45.

Blevin, WR, Brown, WJ, “Total Reflectances of Opaque Diffusers.” J. Opt. Soc. Am. A, 52 (11) 1250–1255 (1962)CrossRef

46.

Klier, K, “Absorption and Scattering in Plane Parallel Turbid Media.” J. Opt. Soc. Am. A, 62 (7) 882–885 (1972)CrossRef

47.

Mudgett, PS, Richards, LW, “Multiple Scattering Calculations for Technology II.” J. Colloid Interface Sci., 39 (3) 551–567 (1972)CrossRef

48.

Rogers, WF, “New Concept in Hydrograph Analysis.” Water Resour. Res., 8 (4) 973–981 (1972)CrossRef

49.

Brinkworth, BJ, “Calculation of Attenuation and Back-Scattering in Cloud and Fog.” Atmos. Environ. (1967), 5 (8) 605–611 (1971)CrossRef

50.

Brinkworth, BJ, “Interpretation of the Kubelka–Munk Coefficients in Reflection Theory.” Appl. Opt., 11 (6) 1434–1435 (1972)CrossRef

51.

Thennadil, SN, “Relationship between the Kubelka–Munk Scattering and Radiative Transfer Coefficients.” J. Opt. Soc. Am. A, 25 (7) 1480–1485 (2008)CrossRef

52.

Gaonkar, HA, Kumar, D, Ramasubramaniam, R, Roy, A, “Decoupling Scattering and Absorption of Turbid Samples Using a Simple Empirical Relation Between Coefficients of the Kubelka–Munk and Radiative Transfer Theories.” Appl. Opt., 53 (13) 2892–2898 (2014)CrossRef

53.

Sandoval, C, Kim, AD, “Deriving Kubelka–Munk Model From Radiative Transport.” J. Opt. Soc. Am. A, 31 (3) 628–636 (2014)CrossRef

54.

Neuman, M, Coppel, LG, Edström, P, “Point Spreading in Turbid Media with Anisotropic Single Scattering.” Opt. Express., 19 (3) 1915–1920 (2011)CrossRef

55.

Joseph, RI, Thomas, ME, “How Accurate is the Kubelka–Munk Theory of Diffuse Reflection? A Quantitative Answer.” In Proc. of SPIE, 2012

56.

Yust, BG, Sardar, DK, Tsin, A, “A Comparison of Methods for Determining Pptical Properties of Thin Samples.” Opt. Interact. with Tissues Cells XXI, 7562 75620C-75620C-9 (2010)

57.

Walowit, E, McCarthy, CJ, Berns, RS, “An Algorithm for the Optimization of Kubelka–Munk Absorption and Scattering Coefficients.” Color Res. Appl., 12 (6) 340–343 (1987)CrossRef

58.

McDonald, R, Colour Physics for Industry. Society of Dyers and Colourists, West Yorkshire (1997)

59.

Marcus, RT, “Determining Dimensioned Values of Kubelka–Munk Scattering and Absorption Coefficients.” Color Res. Appl., 3 (4) 183–187 (1978)CrossRef

60.

Allen, E, “Basic Equations Used in Computer Color Matching.” J. Opt. Soc. Am. A, 56 (9) 1256–1259 (1966)CrossRef

61.

Allen, E, “Basic Equations Used in Computer Color Matching, II Tristimulus Match, Two-Constant Theory.” J. Opt. Soc. Am. A, 64 (7) 991–993 (1974)CrossRef

62.

Peyvandi, S, Amirshahi, SH, Sluban, B, “The Total Colorant Sensitivity of a Color Matching Recipe: An Approach to Colorant Weighting and Tinctorial Strength Errors.” Color Res. Appl., 33 (4) 300–306 (2008)CrossRef

63.

Sluban, B, “Different Measures of Sensitivity of the Recipe Colour to Random and Proportional Dye Concentration Error. Part 1: Definitions, Mutual Relations and Estimates of Maximal Colour Errors.” Color. Technol., 121 (3) 169–177 (2005)CrossRef

64.

Sluban, B, “Comparison of Colorimetric and Spectrophotometric Algorithms for Computer Match Prediction.” Color Res. Appl., 18 (2) 74–79 (1993)CrossRef

65.

Sluban, B, Nobbs, JH, “The Colour Sensitivity of a Colour Matching Recipe.” Color Res. Appl., 20 (4) 226–234 (1995)CrossRef

66.

Sluban, B, Sauperl, O, “Different Measures of Sensitivity of Recipe Colour to Random and Proportional Dye Concentration Error. Part 2: An Example of Target-Position Dependence and Span.” Color. Technol., 121 (5) 281–286 (2005)CrossRef

67.

Sluban, B, Auperl, O, Pozderec, M, “Different Measures of Sensitivity of Recipe Colour to Random and Proportional Dye Concentration Error. Part 3: Observed Repeatability in Regard to Predicted Sensitivity.” Color. Technol., 123 (1) 24–28 (2007)CrossRef

68.

Ramakrishna, M, Hultin, HO, Atallah, MT, “A Comparison of Dogfish and Bovine Chymotrypsins in Relation to Protein Hydrolysis.” J. Food. Sci., 52 (5) 1198–1202 (1987)CrossRef

69.

Gate, LF, “Comparison of the Photon Diffusion Model and Kubelka–Munk Equation with the Exact Solution of the Radiative Transport Equation.” Appl. Opt., 13 (2) 236–238 (1974)CrossRef

70.

Love, RB, Oglesby, S, Gailey, I, “The Relation Between Dye Concentration and Reflectance-Amendments to the Kubelka–Munk Equation.” J. Soc. Dye. Colour., 81 (12) 609–614 (1965)CrossRef

71.

Rundlöf, M, Bristow, JA, “A Note Concerning the Interaction Between Light Scattering and Light Absorption in the Application of the Kubelka–Munk Equations.” J. Pulp Pap. Sci., 23 (5) 220–223 (1997)

72.

Walowit, E, McCarthy, C, Berns, RS, “Spectrophotometric Color Matching Based on Two-Constant Kulbelka–Munk Theory.” COLOR Research and Application, 13 (6) 358–362 (1988)CrossRef

73.

Saunderson, JL, “Calculation of the Color of Pigmented Plastics.” J. Opt. Soc. Am. A, 32 (12) 727–736 (1942)CrossRef

74.

Maheu, B, Gouesbet, G, “Four-Flux Models to Solve the Scattering Transfer Equation: Special Cases.” Appl. Opt., 25 (7) 1122–1128 (1986)CrossRef

75.

Gershun, A, “Fresnel Reflection of Diffusely Incident Light.” J. Opt. Soc. Am. A, 35 (2) 162–163 (1945)CrossRef

76.

Chadwick, RS, Chang, ID, “A Laser Study of the Motion of Particles Suspended in a Slow Viscous Shear Flow.” J. Colloid Interface Sci., 42 (3) 516–534 (1973)CrossRef

77.

Star, WM, Marijnissen, JPA, van Gemert, MJC, “New Trends in Photobiology Light Dosimetry: Status and Prospects.” J. Photochem. Photobiol. B Biol., 1 (2) 149–167 (1987)CrossRef

78.

Auger, JC, Martinez, VA, Stout, B, “Theoretical Study of the Scattering Efficiency of Rutile Titanium Dioxide Pigments as a Function of Their Spatial Dispersion.” J. Coat. Technol. Res., 6 (1) 89–97 (2009)CrossRef

79.

Auger, JC, Stout, B, “Dependent Light Scattering in White Paint Films: Clarification and Application of the Theoretical Concepts.” J. Coat. Technol. Res., 9 (3) 287–295 (2012)CrossRef

80.

Gush, RJ, King, TA, Jayson, MIV, “Aspects of Laser Light Scattering from Skin Tissue with Application to Laser Doppler Blood Flow Measurement.” Phys. Med. Biol., 29 1463–1476 (1984)CrossRef

81.

Twersky, V, “Multiple Scattering of Waves and Optical Phenomena.” J. Opt. Soc. Am., 52 145–171 (1962)CrossRef

Titel: Mathematical and empirical evaluation of accuracy of the Kubelka–Munk model for color match prediction of opaque and translucent surface coatings
verfasst von: M. Gorji Bandpay
F. Ameri
K. Ansari
S. Moradian
Publikationsdatum: 28.03.2018
Verlag: Springer US
Erschienen in: Journal of Coatings Technology and Research / Ausgabe 5/2018
Print ISSN: 1547-0091
Elektronische ISSN: 1935-3804
DOI: https://doi.org/10.1007/s11998-018-0056-5

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