Journal of Textile Research ›› 2024, Vol. 45 ›› Issue (01): 83-89.doi: 10.13475/j.fzxb.20220603301

• Textile Engineering • Previous Articles     Next Articles

Color prediction of fiber-colored fabrics based on Neugebauer equation

YANG Liu1,2, LI Yujia1,2, YU Yan1,2, MA Lei3, ZHANG Ruiyun1,2,4()   

  1. 1. College of Textiles, Donghua University, Shanghai 201620, China
    2. Key Laboratory of Textile Science & Technology, Ministry of Education, Donghua University, Shanghai 201620, China
    3. China Textile Information Center, Beijing 100010, China
    4. Shanghai Belt and Road Joint Laboratory of Textile Intelligent Manufacturing, Shanghai 200051, China
  • Received:2022-06-13 Revised:2023-08-11 Online:2024-01-15 Published:2024-03-14

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Abstract:

Objective Fiber-colored fabrics are woven from a variety of colored fibers, and the fabric color prediction is complicated. According to the stacking of color fibers and the interaction between fiber and incident light, color prediction models convenient for color calculation were established based on the Glassmann' color mixing theory and Neugebauer Equation, and the model was further optimized to predict the color of fabrics for accuracy and efficiency.

Method Color prediction was discussed in two cases: one was depended on the surface layer of colored fibers, and the other was depended on the interaction of the top two-layer fibers. When considering the top two layers of fibers that were superimposed on each other, the mutual stacking was simplified as stacking with the same color or stacking with another color regardless of the number of primary fibers in the fabric. Color prediction models were established according to different calculation methods, and the model with the minimum color difference was selected and optimized.

Results According to different calculation methods, three color prediction models were set up. When the color of fiber-colored fabrics was depended on the surface layer of colored fibers, model 1 was used based on the mixing primary faber colors and the average color difference for all the fabrics was 12.39. When the color of fiber-colored fabrics was depended on the interaction of the top two-layer fibers, models 2 and 3 were used. In this case, considering that the top two layers of fibers were superimposed on each other, the mutual stacking was simplified as stacking with the same color or stacking with another color, regardless of the number of primary fibers in the fabric. The color of fiber-colored fabrics was mixed by 6 primary units in model 2, and its average color difference for all the fabrics was 7.83. The color of fiber-colored fabrics was mixed by 9 primary units in model 3, where unit A+B is different from the unit B+A, but is the same as A+C and B+C. The average color difference using model 3 for all the fabrics was 9.49. Model 2 achieved the smallest average color difference, meaning that when the color of fiber-colored fabrics was depended on the interaction of the top two-layer fibers, the stacking sequence has no effect on the color value of the primary units. This model was optimized by linear regression and the proportion coefficient of each primary unit in the model can be better adopted to predict the color value of fiber-colored fabrics. The new model was named model 4, and its average color difference for all the fabrics was 3.38. The new model 4 was proven to be convenient for prediction of the surface color of fiber-colored fabrics, and could be used as a reference for predicting the color of two-color or three-color mixed fabrics.

Conclusion Based on the Glassmann' color mixing theory and Neugebauer equation, three color prediction models were set up. Model 2 is associated to the smallest average color difference and is further optimized by linear regression. The new model 4 is convenient for predicting the surface color of fiber-colored fabrics, and can be used as a reference for predicting the color of two-color or three-color mixed fabrics. The De Mitchell equation was dupted to calculate the proportion coefficient of the primary units in the Neugebauer equation, and it was found difficult to calculate and required assumptions, resulting in theoretical errors. In this research, the primary units was simplified according to different assumptions, also generated theoretical errors, resulting in model 4 predicting higher color difference than the 1 color difference unit. The primary units of the fiber-colored fabrics is expected to be optimized in future research, fully considering the theoretical error when calculating the primary units proportion.

Key words: Glassmann's theory of color light mixing, fiber-colored fabrics, Neugebauer equation, color prediction, color difference

CLC Number: 

  • TS181.8

Tab.1

Mixing ratio of tricolor fibers"

试样
编号		 色纤维占比/%
1 10 10 80
2 10 20 70
9 20 10 70
36 80 10 10

Tab.2

Tristimulus values of primary fibers"

纤维颜色 X Y Z
21.03 12.29 7.68
46.26 41.65 4.40
8.26 8.86 26.41

Tab.3

Mixing parameters of tricolor fabrics in prediction model 2#"

色元数量i 基本
色元		 色元占比fi 色元三
刺激值
1 A+A a2 X 1 Y 1 Z 1
2 B+B b2 X 2 Y 2 Z 2
3 C+C c2 X 3 Y 3 Z 3
4 A+B/B+A 2ab X 4 Y 4 Z 4
5 A+C/C+A 2ac X 5 Y 5 Z 5
6 B+C/C+B 2bc X 6 Y 6 Z 6

Fig.1

Light path diagram of interaction of light and fiber-colored fabric"

Tab.4

Color prediction results of fiber-colored fabrics"

混色织物 色差 模型1# 模型2# 模型3#
红+黄 最大值 11.93 7.41 9.23
最小值 3.19 0.36 1.57
均值 8.72 4.73 6.65
红+蓝 最大值 9.45 5.54 6.60
最小值 3.69 0.70 1.94
均值 6.81 3.89 5.05
黄+蓝 最大值 28.38 17.99 21.16
最小值 11.04 4.77 6.34
均值 20.22 12.14 14.66
三彩色混 最大值 26.46 16.46 20.03
最小值 5.67 3.98 4.52
均值 12.75 8.51 10.01
总均值 12.39 7.83 9.49

Tab.5

Linear regression coefficients"

色元数量i U i V i W i
1 19.69 12.33 7.61
2 33.93 31.08 5.15
3 13.78 12.19 23.75
4 22.24 13.18 4.93
5 0.26 2.46 12.01
6 4.07 4.15 5.52

Fig.2

Comparison of color difference before and after correction of prediction model"

[1] 钱爱芬. 色纺纱产品特点及调配色原理[J]. 棉纺织技术, 2010, 38(11):66-68.
QIAN Aifen. Colored spun yarn characteristic and color mixing & matching principle[J]. Cotton Textile Technology, 2010, 38(11):66-68.
[2] WALOWIT E, MCCARTHY C J, BERNS R S. An algorithm for the optimization of Kubelka-Munk absorption and scattering coefficients[J]. Color Research & Application, 2010, 12(6):340-343.
[3] STEARNS EI, NOECHEL F. Spectrophotometric prediction of color of wool blends[J]. American Dyestuff Reporter, 1944, 33(9):177-180.
[4] FRIELE L F C. The application of colour measurement in relation to fiber blending[J]. Journal of the Textile Institute Proceedings, 1952, 43(8) :604-611.
[5] YANG Ruihua, XU Yaya, DENG Qianqian, et al. Kubelka-Munk double constant theory of digital rotor spun color blended yarn[J]. Dyes and Pigments, 2019, 165:151-156.
doi: 10.1016/j.dyepig.2019.02.008
[6] YANG Ruihua, XU Yaya, HAN Ruiye. Friele model of rotor spun multi-primary-colour-blended yarn[J]. Fibres and Textiles in Eastern Europe, 2019, 27, 5(137):50-59.
[7] ZHANG Ge, ZHOU Jian, PAN Ruru, et al. Color prediction for pre-colored cotton fiber blends based on improved Kubelka-Munk double-constant theory[J]. Fibers and Polymers, 2021, 22(2):412-420.
doi: 10.1007/s12221-021-9371-z
[8] 黄紫娟, 李加林, 周砚江. 单层数码仿真彩色提花丝织物颜色模型的研究[J]. 浙江理工大学学报, 2007, 24(4):1673-3851.
HUANG Zijuan, LI Jialin, ZHOU Yanjiang. Research on color model of single-layer digital simulation color of jacquard silk fabric[J]. Journal of Zhejiang Sci-Tech University, 2007, 24(4):1673-3851.
[9] 黄紫娟. 一经一纬单层色织物明度模型建立初探[J]. 国外丝绸, 2008(4): 33-35.
HUANG Zijuan. A preliminary study on the lightness model of one warp and one weft single-layer colored fabric[J]. Foreign Silk, 2008(4): 33-35.
[10] 温小丽. 异色经纬交织织物的混色效应研究[D]. 苏州: 苏州大学, 2010:60.
WEN Xiaoli. Study on the color mixing effect of different color warp and weft interwoven fabrics[D]. Suzhou: Soochow University, 2010:60.
[11] 王红伟, 陈浩杰. 浅谈纽介堡方程的理论价值及应用局限性[J]. 广东印刷, 2014(6):13-14.
WANG Hongwei, CHEN Haojie. Discusses the theoretical value and application limitations of Newburg equation[J]. Guangdong Printing, 2014(6):13-14.
[12] 杨柳, 李羽佳, 张鑫. 色纺针织物紧密程度对颜色预测的影响[J]. 纺织学报, 2022, 43(5):104-108.
YANG Liu, LI Yujia, ZHANG Xin, et al. Effect of tightness of fiber-colored knitted fabric on color prediction[J]. Journal of Textile Research, 2022, 43(5):104-108.
[13] 赵林, 姚穆. 纤维反光和透光性质的研究[J]. 西北纺织工学院学报, 2001, 15(2):207-212.
ZHAO Lin, YAO Mu. Study on the reflective and transmitting properties of fibers[J]. Journal of Northwest Institute of Textile Science and Technology, 2001, 15(2):207-212.
[14] 刘浩学. 印刷色彩学[M]. 北京: 中国轻工业出版社, 2008:52-53.
LIU Haochun. Printing color science[M]. Beijing: China Light Industry Press, 2008:52-53.
[15] 成刚虎, 王西珍. 纽介堡方程应用误差的理论探析[J]. 西安理工大学学报, 2011(27):74-78.
CHEN Ganghu, WANG Xizhen. Application error analysis to neugebauer equation[J]. Journal of Xi'an University of Technology, 2011(27):74-78.
[16] WEI Chun'ao, WAN Xiaoxia, LI Junfeng. A modified single-constant Kubelka-Munk model for color prediction of pre-colored fiber blends[J]. Cellulose, 2018, 25:2091-2102.
doi: 10.1007/s10570-018-1669-7
[17] 易清珠. 基于全局与局部特征的涤纶色纤维混合呈色研究[D]. 上海: 东华大学, 2021:44.
YI Qingzhu. Research on the mixed color rendering of polyester color fibers based on global and local characteristics[D]. Shanghai: Donghua University, 2021: 44.
[18] 张瑞, 周世生. 基于纽介堡方程的柔版印刷呈色模型探讨[J]. 包装工程, 2010, 31(5):96-98.
ZHANG Rui, ZHOU Shisheng. Discussion on the color rendering model of flexographic printing based on the Newcastle equation[J]. Packaging Engineering, 2010, 31(5):96-98.
[19] 张桢杰, 刘真. 3种基于分区纽介堡方程的分色算法的误差分析[J]. 包装工程, 2012, 33(15):88-91.
ZHANG Zhenjie, LIU Zhen. Errors analysis of three color separation algorithms based on subarea Neugebauer equation[J]. Packaging Engineering, 2012, 33(15) :88-91.
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[14] . Color fiber mixing formula algorithm based on Friele model [J]. JOURNAL OF TEXTILE RESEARCH, 2017, 38(12): 33-37.
[15] . Model for predicting color mixing of dope-dyed polyester interwoven fabrics [J]. JOURNAL OF TEXTILE RESEARCH, 2017, 38(07): 56-62.
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