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Research on Multispectral Dimension Reduction Method Based on Weight Function Composed of Spectral Color Difference |
CAO Qian, MA Xiang-cai, BAI Chun-yan, SU Na, CUI Qing-bin |
Department of Printing and Packaging Engineering, Shanghai Publishing and Printing College, Shanghai 200093, China
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Abstract The reflectance spectrum has a high dimension and has nothing to do with illumination and observation. It can truly and objectively describe the color information of an object. The characteristics of the object itself determine it, so it is called the "fingerprint" of the object. However, the amount of reflectance spectra data is more than ten times that of the traditional three-color system, and these huge spectral data cause huge burdens in terms of storage, data processing, and data transfer, and they spend too much computing time. Suppose the high-dimensional spectrum can be mapped to the low-dimensional space through mathematical transformation methods, and ensure that the low-dimensional space data can better represent the information covered by the original spectrum. In that case, the multi-spectral data can be effectively compressed and the processing efficiency of spectrum-based color reproduction can be improved. PCA treats all wavelengths in the visible range equally, and the reconstructed spectrum is only a mathematical approximation to the original spectrum, which often leads to the problem of small spectral reconstruction error and significant colorimetric reconstruction error. A multispectral dimension reduction algorithm based on the weight function of spectral color difference is proposed in this paper. The dimensionality of Munsell was reduced to one dimension by PCA and then restored to 31 dimensions, and the average spectral color difference between Munsell's original spectrum and its reconstructed spectrum was used as a weight function. Taking NCS as the training sample and NCS, Munsell and 3 multispectral images as the test samples respectively, the performance of the proposed method of this paper and the classical PCA and the other four weighted PCA are analyzed and compared. CIELAB color difference under the conditions of multiple Lighting and viewing (D65/2° and A/2°) and root mean square error (RMSE) evaluate the colorimetric and spectral reconstruction accuracy between the original spectra and the reconstructed spectra of the test sample respectively. The experimental results show that: compared with PCA, the proposed method has greatly improved colorimetric reconstruction accuracy at the expense of a small amount of spectral reconstruction accuracy. The improvement of colorimetric reconstruction accuracy is very important for spectral color reproduction. The results also show that the colorimetric reconstruction accuracy of the proposed method is better than that of the other four existing weighted PCA.
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Received: 2022-03-01
Accepted: 2022-11-11
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[1] Habib T, Green P, Nussbaum P. In Proc. IS&T Int'. Symp. on Electronic Imaging: Color Imaging XXV: Displaying, In Processing, Hardcopy, and Applications, 2020: 121.
[2] Mohtasham J, Nateri A S, Khalili H. Color. Technol., 2012, 128(3): 199.
[3] Shen D, Zhang L, Liang D, et al. Laser Phys., 2017, 27(7): 075201.
[4] Rayat A, Amirshahi S, Agahian F. Color Res. Appl., 2014, 39(2): 136.
[5] Hajipour A, Shams Nateri A. Color Res. Appl., 2017, 42(2): 182.
[6] Laamanen H, Jetsu T, Jaaskelainen T, et al. JOSA A, 2008, 25(6): 1383.
[7] WANG Ying, WANG Zhong-min, WANG Yi-feng, et al(王 莹,王忠民,王义峰,等). Optics and Precision Engineering(光学精密工程), 2011, 19(5): 1171.
[8] Tian J, Tang Y. Opt. Lett., 2013, 38(15): 2818.
[9] Wu G, Liu Z, Fang E, et al. Optik, 2015, 126(11-12): 1249.
[10] Cao Q, Wan X, Li J, et al. Opt. Rev., 2016, 23(5): 753.
[11] LIU Shi-wei, LIU Zhen, TIAN Quan-hui, et al(刘士伟,刘 真,田全慧,等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2017, 37(5): 1601.
[12] LIANG Jin-xing, WAN Xiao-xia, LU Wei-pent(梁金星,万晓霞,卢玮朋). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2017, 37(1): 177.
[13] Ma X, Wang, X, Zhang, D. Optik, 2020, 203: 163959.
[14] Viggiano J A S. Advanced Printing of Conference Summaries: SPSE's 43rd Annual Conference, 1990: 222.
[15] Viggiano J A S. 9th Congress of the International Colour Association. International Society for Optics and Photonics, 2002, 4421: 701.
[16] University of Eastern Finland, Spectral Color Research Group: https://www.uef.fi/spectral/spectral-databas.
[17] Yasuma F, Mitsunaga T, Iso D, et al. IEEE Transactions on Image Processing, 2010, 19(9): 2241.
[18] Imai F H, Berns R S, Tzeng D Y. J. Imaging Sci. Techn., 2000, 44(4): 280.
[19] Imai F H, Rosen M R, Berns R S. First European Conference on Color in Graphics, Imaging, and Vision. Conference Proceedings, 2002, 2002(1): 492.
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