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| Study on the Derivation of Paper Viscosity Spectral Index Based on Spectral Information Expansion |
| GAO Yu1, SUN Xue-jian1*, LI Guang-hua2, ZHANG Li-fu1, QU Liang2, ZHANG Dong-hui1, CHANG Jing-jing2, DAI Xiao-ai3 |
1. National Engineering Laboratory for Remote Sensing Satellite Applications, Aerospace Information Research Institute, Chinese Academy of Sciences, Beijing 100101, China
2. The Palace Museum, Beijing 100009, China
3. College of Earth Sciences, Chengdu University of Technology, Chengdu 610059, China
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Abstract Viscosity is an important index reflecting paper cellulose's degree of polymerization and physical properties. Accurate real time information on viscosity is important for repairing and protecting precious paper materials. However, the traditional paper's viscosity analysis method mainly uses chemical means, which takes a long time and will inevitably cause secondary damage to the paper. To solve this problem, hyperspectral remote sensing, with its rich information and real-time, contactless characteristics, is an effective way to obtain the paper's viscosity content without damage. First, obtain experimental papers with different aging degrees in the laboratory to measure their viscosity contents, collect hyperspectral data of paper samples, preprocess paper samples hyperspectral data through spectral noise reduction, spectral transformation, and spectral information expansion, establish a spectral database of paper's viscosity contents under different aging degrees, and respectively build spectral difference index, ratio index and normalization index under different spectral transformation methods. Correlation analyses were carried out the 12 best spectral indices with the strongest correlation with viscosity were selected. Finally, the selected spectral indices were used as independent variables to build a regression model on the viscosity content. We also selected the spectral index and model that best characterized the change of the paper's viscosity content by comparing model accuracy. The results show that: (1) Compared with the original spectrum, the proportion of the highly correlated feature subset of viscosity extracted after spectral transformation processing greatly improved along with the mean and median of the correlation coefficient; (2) The correlation between the spectral information parameters (obtained by spectral information expansion) and viscosity is higher than that of the original spectral segment, and most of the 12 optimal spectral indices extracted have the participation in the expanded information parameters; (3) The correlation between the best spectral index, extracted under different spectral transformation results, and the viscosity content above 0.89, and the three representative spectral indices selected from them effectively reflected the change of paper's viscosity at 400~500 mL·g-1; (4) After logarithmic first-order differential treatment of the paper spectrum, the normalized index constructed by spectral integration and spectral absorption depth has the largest correlation with viscosity, reaching -0.917 and the R2 of the model established by this index in the training set and the test set is 0.84 and 0.76 respectively, with MRE and RMSE in the test set as 0.089 and 40.29 mL·g-1, respectively. The research results can provide scientific theory and technical support for the remote sensing inversion of the paper's viscosity content, and have important reference significance for the construction of the non-destructive analysis system of paper cultural relics.
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Received: 2023-02-23
Accepted: 2023-06-08
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Corresponding Authors:
SUN Xue-jian
E-mail: sunxj201494@aircas.ac.cn
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[1] LÜ Shu-xian(吕淑贤). Study on the Protection of Ancient Books(古籍保护研究), 2020,(2): 73.
[2] TIAN Zhou-ling,ZHANG Ming,REN Shan-shan, et al(田周玲,张 铭,任珊珊, 等). Sciences of Conservation and Archaeology(文物保护与考古科学), 2019, 31(1): 65.
[3] YU Hui,CHEN Gang,ZHONG Jiang, et al(余 辉,陈 刚,钟 江, 等). Journal of Fudan University(Natural Science)[复旦学报(自然科学版)], 2016, 55(6): 677.
[4] TONG Qing-xi,ZHANG Bing,ZHANG Li-fu(童庆禧,张 兵,张立福). National Remote Sensing Bulletin(遥感学报), 2016, 20(5): 689.
[5] SUN Yu,LIU Jia-jun,ZHAO Ying-jun, et al(孙 雨,刘家军,赵英俊, 等). Geology in China(中国地质), 2022, 49(2): 558.
[6] Zhang L S, Zhang L F, Cen Y, et al. Remote Sensing, 2022, 14(13): 3077.
[7] LIU Mei,MA Qi-liang,YUAN Ju-lin, et al(刘 梅,马启良,原居林, 等). Oceanologia et Limnologia Sinica(海洋与湖沼), 2022, 53(1): 195.
[8] LI Min,DIAO Chang-yu,GE Yun-fei, et al(李 敏,刁常宇,葛云飞, 等). National Remote Sensing Bulletin(遥感学报), 2021, 25(12): 2351.
[9] WU Feng-qiang,YANG Wu-nian,LI Dan(武锋强,杨武年,李 丹). The Journal of Light Scattering(光散射学报), 2014, 26(1): 88.
[10] CEN Yi,ZHANG Lin-shan,SUN Xue-jian, et al(岑 奕,张琳姗,孙雪剑, 等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2019, 39(4): 1136.
[11] Fischer C, Hsieh E. Journal of Archaeological Science, 2017, 80: 14.
[12] Zhao H, Wang Y, Liu S, et al. Journal of Archaeological Science, 2019, 111: 105026.
[13] Alicandro M, Candigliota E, Dominici D, et al. Land, 2022, 11(11): 2070.
[14] SHI Ning-chang,LI Guang-hua,LEI Yong, et al(史宁昌,李广华,雷 勇, 等). Sciences of Conservation and Archaeology(文物保护与考古科学), 2017, 29(3): 23.
[15] HUANG Hua,LI Mao-yi,CHEN Yin-hui, et al(黄 华,李茂亿,陈吟晖, 等). Water Resources Protection(水资源保护), 2021, 37(5): 36.
[16] Jin X, Song K, Du J, et al. Agricultural and Forest Meteorology, 2017, 244: 57.
[17] ZHANG Dong-hui,ZHAO Ying-jun,QIN Kai, et al(张东辉,赵英俊,秦 凯, 等). Transactions of the Chinese Society of Agricultural Engineering(农业工程学报), 2018, 34(20): 141.
[18] CONG Li-juan,JIA Zhi-ye,LIANG Xiu-juan, et al(丛丽娟,贾志业,梁秀娟, 等). Earth Science Frontiers(地学前缘), 2017, 24(5): 299.
[19] PAN Yue,CAO Hong-xin,QI Jia-guo, et al(潘 月,曹宏鑫,齐家国, 等). Jiangsu Journal of Agricultural Sciences(江苏农业学报), 2022, 38(6): 1550.
[20] LÜ Hang,MA Wei-chun,ZHOU Li-guo, et al(吕 航,马蔚纯,周立国, 等). Journal of Fudan University(Natural Science)[复旦学报(自然科学版)], 2013, 52(2): 238.
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