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| Research on Classification Method of Main Poisonous Plants in Alpine Meadow Based on Spectral Characteristic Variables |
| DONG Rui, TANG Zhuang-sheng, HUA Rui, CAI Xin-cheng, BAO Dar-han, CHU Bin, HAO Yuan-yuan, HUA Li-min* |
Grassland College of Gansu Agricultural University,Key Laboratory of Grassland Ecosystem Ministry of Education,Engineering and Technology Research Center for Alpine Rodent Pest Control,National Forestry and Grassland Administration,Lanzhou 730070, China
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Abstract The extension of poisonous plants in alpine meadows is one of the main problems of the grassland ecosystem in the Qinghai-Tibet Plateau. The classification technology of poisonous plants in alpine meadows is of great significance for timely monitoring, scientific preventing and controlling changes in grassland communities. In recent years, poisonous plants species and harmful areas have increased rapidly. Traditional manual field surveys were time-consuming and laborious, and poorly represented the survey results. At the same time, poisonous plants have certain differences in geographical distribution, so it is not easy to conduct large-scale investigations by the workforce. Hyperspectral remote sensing technology has great advantages in the fine classification of poisonous plants due to its high resolution, multiple bands, integration of maps, and so on, which can meet the needs of fast, accurate, and large-scale acquisition of poisonous plants. Some scholars have carried out studies on the spectral reflectance characteristics of grassland plants, which proved that the spectral reflectance characteristics of plants could effectively distinguish their species. On the contrary, there are few reports on the selection of spectral reflectance characteristics variables of poisonous plants and the construction of a predictive classification model based on the spectral characteristics of poisonous plants. In this study, 11 kinds of main poisonous plants field spectrum data on alpine meadows, including Oxytropis ochrocephala, O latibracteata, Astragalus polycladus, Saussurea hieracioides, Ligularia virgaurea, Anaphalis lactea, Cirsium souliei, Stellera chamaejasme, Elsholtzia Densa, Aconitum gymnandrum, and Pedicularis cheilanrthifolia (in Tianzhu County and Maqu County, Gansu Province) were collect by using the SOC710VP near-infrared hyperspectral imager. The Savitzky-Golay convolution smoothing algorithm (SG) was applied to denoise the original spectral values, the first-order differential derivative (FD) was used to carry out spectral feature analysis, and the canonical discriminant analysis (CDA) was performed to sort the absolute values of the standardized score coefficients of 16 selected spectral feature variables. Then from the size of large to small, they were added to 5 algorithms, namely random forest (RF), support vector machine-radial kernel function (SVM-RBF), k-nearest neighbor classification (KNN), naive bayes (NB), and decision tree (CART) to construct classification models and screen the best feature variables, and the confusion matrix was used to evaluate the classification effects. The results showed that: (1) The overall classification accuracy of canonical discriminant analysis (CDA) for 16 spectral characteristic variables was 92.34%, R2=0.89; (2) The best classification spectral characteristic variables were selected as green peak amplitude (Mg), blue edge area (Ab), red edge amplitude (Mre), red edge area (Are), red edge position (Lre), NDVI2, and RVI1; (3) The selected 7 spectral characteristic variables were used to classify poisonous plants, and then the SVM-RBF has the best classification effects, with an accuracy of 96.45%.
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Received: 2021-05-22
Accepted: 2021-08-11
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Corresponding Authors:
HUA Li-min
E-mail: hualm@gsau.edu.cn
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[1] Yao X X, Wu J P, Gong X Y, et al. Ecological Engineering, 2019, 130: 80.
[2] ZHAO Bao-yu, LIU Zhong-yan, WAN Xue-pan, et al(赵宝玉,刘忠艳,万学攀,等). Scientia Agriculture Sinica(中国农业科学), 2008, 41(10): 3094.
[3] HUANG Mei, SHANG Zhan-huan(黄 梅,尚占环). Acta Agrestia Sinica(草地学报), 2019, 27(5): 1107.
[4] ZHAO Shi-jiao, ZHAO Hong-yang, GAO Dan, et al(赵世姣,赵红阳,高 丹,等). Acta Agrestia Sinica(草地学报), 2017, 25(6): 1389.
[5] ZHU Ning, WANG Hao, NING Xiao-gang, et al(朱 宁,王 浩,宁晓刚,等). Science of Surveying and Mapping(测绘科学), 2020, 46(5): 66.
[6] YU Lu, WANG Xun, CHAI Sha-tuo, et al(于 璐,王 迅,柴沙驼,等). Acta Agrestia Sinica(草地学报), 2020, 28(2): 547.
[7] Baron J, Hill D J. Remote Sensing of Environment, 2020, 249: 112008.
[8] HAN Wan-qiang, JIN Gui-li, YUE Yong-huan, et al(韩万强,靳瑰丽,岳永寰,等). Acta Agrestia Sinica(草地学报), 2020, 28(4): 1153.
[9] MA Wen-qiang, ZHANG Man, LI Yuan, et al(马文强,张 漫,李 源,等). Chinese Journal of Analytical Chemistry(分析化学), 2020, 48(12): 1737.
[10] WEI Ya-hui, ZHAO Bao-yu, WEI Shuo-nan, et al(尉亚辉,赵宝玉,魏朔南,等). Major Species and Distribution of Poisonous Plants in Natural Grasslands of Western China(中国西部天然草地毒害草主要种类及分布). Beijing: Science Press(北京:科学出版社),2018. 11.
[11] ZENG Shuai, KUANG Run-yuan, XIAO Yang, et al(曾 帅,况润元,肖 阳,等). Remote Sensing Information(遥感信息), 2017, 32(5): 75.
[12] YI Da, LI Yuan-qiao, YANG Yu(易 达,李院瞧,杨 宇). Software(软件), 2020, 41(7): 45.
[13] Shi X, Song J, Wang H, et al. European Journal of Remote Sensing, 2020, (4): 1.
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