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Abstract

Combing the color transmission image and the Beer–Lambert law shows a great application prospect in quantifying each material in multilayer specimen. Here, a novel, low-cost, and efficient optical algorithm is proposed to predict the thickness of each color material in a multilayer specimen from the color transmission image based on the Beer–Lambert Law. In this work, a normal scanner is employed to achieve the color transmission image of the monochrome transparent films. RGB values represent the transmitted intensity. A linear relationship between the optical depth and physical thickness is observed under different monochromatic lights. It is supposed that for a multilayer transparent film which consisted of different monochrome transparent films, the optical depth is related to the physical thickness of each monochrome transparent component. Therefore, an estimating equation is proposed to predict the thickness of each color material in the multilayer specimen. According to the result, the standard deviation of predicted thickness and practical thickness of each color film in the multilayer specimen is 0.93%. Fairly good agreement and high accuracy are obtained between the practical and predicted values, and the validity of this method is confirmed.

Keywords

physical optics color instrumentation measurement and metrology digital image processing

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References

Alcicek

Balaban

. Development and application of “The Two Image” method for accurate object recognition and color analysis. J Food Eng 2012; 111(1): 46–51.

Godinho

MdS

Pereira

Ribeiro

KdO

, et al. Carbonated soft drink classification based on image analysis and PCA. Quim Nova 2008; 31(6): 1485–1489.

Balaban

Sengor

GFU

Soriano

, et al. Quantification of gaping, bruising, and blood spots in salmon fillets using image analysis. J Food Sci 2011; 76(3): E291–E297.

Huang

Yang

, et al. Adaptive classifier allows enhanced flow contrast in OCT angiography using a histogram-based motion threshold and 3D Hessian analysis-based shape filtering. Optics Lett 2017; 42(23): 4816–4819.

Frucci

Riccio

di Baja

, et al. Severe: Segmenting vessels in retina images. Pattern Recogn Lett 2016; 82: 162–169.

Farid

Adelson

. Separating reflections from images by use of independent component analysis. J Opt Soc Am A-Opt Image Sci Vis 1999; 16(9): 2136–2145.

Jang

Jin

Javidi

. Three-dimensional integral imaging with large depth of focus by use of real and virtual image fields. Optics Lett 2003; 28(16): 1421–1423.

Hida

Satoh

Okuyama

. Discrimination analysis of adhesive paper tapes with scanned digital images. Bunseki Kagaku 2011; 60(11): 853–858.

Li A, Ye D, Lyu E, et al., editors. RGB-Thermal Fusion Network for Leakage Detection of Crude Oil Transmission Pipes. In: 2019 IEEE International Conference on Robotics and Biomimetics (ROBIO); 2019: IEEE.

10.

Aujol

J-F

Kang

. Color image decomposition and restoration. J Visual Comm Image Represent 2006; 17(4): 916–928.

11.

Kiire

Barada

Sugisaka

J-I

, et al. Color digital holography using a single monochromatic imaging sensor. Optics Lett 2012; 37(15): 3153–3155.

12.

Chen

, et al. 3D double-faced interlock fabric triboelectric nanogenerator for bio-motion energy harvesting and as self-powered stretching and 3D tactile sensors. Mater Today 2020. 32: 84–93. .

13.

Funamizu

Tokuno

Aizu

. Estimation of spectral transmittance curves from RGB images in color digital holographic microscopy using speckle illuminations. Optic Rev 2016; 23(3): 535–543.

14.

Dadabayev

Shabairou

Zalevsky

, et al. A visible light RGB wavelength demultiplexer based on silicon-nitride multicore PCF. Optics Laser Technol 2019; 111: 411–416.

15.

Tao

Zhu

Sun

, et al. Hyperspectral image recovery based on fusion of coded aperture snapshot spectral imaging and RGB images by guided filtering. Optics Comm 2020; 458: 124804.

16.

de Almeida

da Costa

Fernandes

DDD

, et al. Using color histograms and SPA-LDA to classify bacteria. Anal Bioanal Chem 2014; 406(24): 5989–5995.

17.

Milanez

Pontes

MJC

. Classification of edible vegetable oil using digital image and pattern recognition techniques. Microchem J 2014; 113: 10–16.

18.

Subr

Soler

Durand

. Edge-preserving multiscale image decomposition based on local extrema. ACM Transact Graphics 2009; 28(5).

19.

Tan

Lien

Gingold

. Decomposing Images into Layers via RGB-Space Geometry. ACM Transact Graphics 2017; 36(1).

20.

McCann

Pollard

. Local layering. ACM Transact Graphics 2009; 28(3).

21.

Tan

Dvoroznak

Sykora

, et al. Decomposing time-lapse paintings into layers. ACM Transact Graphics 2015; 34(4).

22.

Mery

Pedreschi

. Segmentation of colour food images using a robust algorithm. J Food Eng 2005; 66(3): 353–360.

23.

Shofner FM, Zhang Y, Shofner CK, inventors; Shofner Eng Assoc Inc, assignee. Image-based length measurement apparatus for measuring length of e.g. cotton, has digital computer system for determining fiber amount as function of one-dimensional distance from dual-beard needle sampler. Patent US2007291270-A1; US7345756-B2.

24.

H-Y

Wang

F-M

. A new method for fiber length measurements - Dual-beard method. Industr Text 2015; 66(3): 117–122.

25.

Jingye

Bugao

Fumei

. Measurement of short fiber contents in raw cotton using dual-beard images. Text Res J 2016; 88(1): 14–26.

26.

Calloway

. Beer-Lambert law. J Chem Educ 1997; 74(7): 744.

27.

Mitschele

. Beer-Lambert Law. J Chem Educ 1996; 73(11): A260–A261.

Quantifying the thickness of each color material in multilayer transparent specimen based on transmission image

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