Abstract:Aim In order to maintain the chromaticity precision in the process of linear compression of the multispectral data, a visual perception-referenced compression method (VPCM) based on the chroma gradient (refer to the partial derivative of chroma to wavelength) is proposed. Method The method firstly successfully developed the transfer functions which could synchronously fusion the spectral features and chromaticity characteristics of human visuals based on the nonlinear analytic feature of human visual system. For further improvement the transfer function, a modified optimizing function was developed to help find out the optimal transfer direction for different sample sets. If the transfer function was finally settled, it will be applied to transforming the spectral data of the sample set (Γ(S)=C). Then the transformed spectral data of the sample set will be compressed with high chromatic accuracy by the principle components analysis method. After that, the compressed data will be reconstructed through inverse transformation (Γ-1(C)=), while the reconstructed spectral data will be using to evaluate the effective of the proposed VPCM method. Result Four groups typical and representative sample sets were chosen to test the effective of the proposed method. The CIELab color difference in the D50/2° calculates condition and a proposed mean metamerism index (MMI) calculated with 75 groups typical light sources (including tungsten, fluorescent and LED lamp) was adopted as evaluating metrics. Eventually, the comparative experiment involving several existing methods Lab-PQR and 2-XYZ indicates that the proposed VPCM hold the best chromatic accuracy both for metric MMI and the average color difference ΔEab when compared with Lab-PQR and 2-XYZ, and the spectral accuracy was calculated between Lab-PQR and 2-XYZ with Lab-PQR maintained the highest spectral accuracy. Conclusion The proposed VPCM can preserve high compression chromatic precision at the price of small loss of spectral precision and possess good colorimetric stability under variable reference conditions. It is very applicable for some application fields which require compressing of the multi-spectral data with high chromatic accuracy.
梁金星,万晓霞*,卢玮朋 . 基于视感知特征的多光谱高保真降维方法研究 [J]. 光谱学与光谱分析, 2017, 37(01): 177-182.
LIANG Jin-xing, WAN Xiao-xia*, LU Wei-peng . Research on Visual Perception-Referenced Compression Method for Multi-Spectral Data with High-Fidelity . SPECTROSCOPY AND SPECTRAL ANALYSIS, 2017, 37(01): 177-182.
[1] Rosen M R, Ohta N. Spectral Color Processing Using an Interim Connection Space. In the 11th Color Imaging Conference Proceedings. Springerfield, VA: IS&T, 2003. 187. [2] Li Z, Berns R S. Color Research & Application, 2007, 32(4): 293. [3] Lissner I, Urban P. Image Processing, IEEE Transactions on, 2012, 21(3): 1153. [4] Tzeng D Y, Berns R S. Color Research & Application, 2005, 30(2): 84. [5] Zhang X, Xu H. JOSA A, 2008, 25(2): 371. [6] Tian J, Tang Y. Optics Letters, 2013, 38(15): 2818. [7] Hannu Laamanen, Tuija Jetsu, Timo Jaaskelainen, et al. J. Opt. Soc. Am., 2008, 25: 1383. [8] Derhak M, Rosen M. Journal of Imaging Science and Technology, 2006, 50(1): 53. [9] Tsutsumi S H, Rosen M R, Berns R S. Color Res. Appl., 2008, 33: 282. [10] Zhang X, Wang Q, Li J, et al. JOSA A, 2012, 29(6): 1027. [11] Wyszecki G,Stiles W S. Color Science; Concepts and Methods, Quantitative Data and Formulas, 2nd ed. Wiley, New York, 1982. 256. [12] Wang Ying,Wang Zhongmin,Wang Yifeng,et al. Optics and Precision Engeerning,2011, 19(5): 1171. [13] Stephen-Viggiano J A. Metrics for Evaluating Spectral Matches: A Quantitative Comparison//Proc. of CGIV2004: The Second European Conference on Colour, Graphics, Imaging and Vision. 2004. [14] Fairman H S. Color Res. Appl., 1987, 12: 261. [15] The National Gallery, London, “Spectral Power Distribution (SPD) Curves”. http: //research.ng?london.org.uk/scientific/spd/.
