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Home > Archive>Volume 45, Issue 1, 2025 >82-93. DOI:10.13961/j.cnki.stbctb.2025.01.010
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Characteristics of spatial-temporal changes and its driving factors in understory vegetation coverage in Hubei Province
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Q948.1,S157

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    Abstract:

    [Objective] The temporal and spatial variation of understory vegetation coverage and its driving factors in Hubei Province were studied to provide scientific basis for ecological environment protection and vegetation management in this area. [Methods] Hubei Province was selected as the study area, and understory green leaf vegetation cover and understory litter cover were extracted from 28 sample plots for every half month in 2022 through field survey and DeepLabV3+ semantic segmentation method. Based on this, various machine learning models were used to analyze the impact of four driving factors, namely spatial location, natural environment, social and economic environment, and climate conditions, on changes in understory green leaf vegetation cover. [Results] Monthly variations in understory litter cover did not show obvious seasonal characteristics, and there was considerable spatial and temporal heterogeneity in the understory litter cover among the sample plots. In contrast, understory green leaf vegetation cover showed obvious seasonal change characteristics, and there were significant differences in understory green leaf vegetation cover among different vegetation types; the understory green leaf vegetation cover of economic forests and conifers was generally higher than that of broadleaf deciduous forests and evergreen broadleaf forests, and the differences in understory green leaf vegetation cover between broadleaf deciduous and evergreen broadleaf forests were relatively small. The random forest regression model showed the best prediction performance, with a root mean square error (RMSE) of 11.072 3 and a coefficient of determination (R2) of 0.732. [Conclusion] The random forest regression model showed that temperature, NDVI, and precipitation in the previous month were the key driving factors for spatiotemporal changes in the understory green leaf vegetation cover.

    Reference
    [1] 郑城,程岚,牛俊文,等.浙江省林下植被盖度时空变化研究[J].水利规划与设计,2023(2):64-70. Zheng Cheng, Cheng Lan, Niu Junwen, et al. Temporal and spatial variation of understory vegetation coverage in Zhejiang Province [J]. Water Resources Planning and Design, 2023(2):64-70.
    [2] Venier L A, Swystun T, Mazerolle M J, et al. Modelling vegetation understory cover using LiDAR metrics [J]. PLoS One, 2019,14(11):e0220096.
    [3] Nilsson M C, Wardle D A. Understory vegetation as a forest ecosystem driver: Evidence from the Northern Swedish boreal forest [J]. Frontiers in Ecology and the Environment, 2005,3(8):421-428.
    [4] Law B E, Waring R H. Remote sensing of leaf area index and radiation intercepted by understory vegetation [J]. Ecological Applications, 1994,4(2):272-279.
    [5] 焦桐,刘荣高,刘洋,等.林下植被遥感反演研究进展[J].地球信息科学学报,2014,16(4):602-608. Jiao Tong, Liu Ronggao, Liu Yang, et al. The progress of forest understory retrieval from remote sensing [J]. Journal of Geo-Information Science, 2014,16(4):602-608.
    [6] 丁松,应学亮,吕丹,等.赣南飞播马尾松林林下植被盖度对土壤质量的影响[J].水土保持研究,2014,21(3):31-36. Ding Song, Ying Xueliang, Lü Dan, et al. Effects of understory vegetation coverage on soil quality of aerial seeding pinus massoniana stands in south of Jiangxi Province [J]. Research of Soil and Water Conservation, 2014,21(3):31-36.
    [7] Nearing M A, Jetten V, Baffaut C, et al. Modeling response of soil erosion and runoff to changes in precipitation and cover [J]. CATENA, 2005,61(2/3):131-154.
    [8] Han Chunming, Liu Jia, Ding Yixing, et al. Recognition of area without understory vegetation based on the RGB-UAV ultra-high resolution images in red soil erosion area [J]. Remote Sensing, 2023,15(5):1470.
    [9] Légaré S, Bergeron Y, Leduc A, et al. Comparison of the understory vegetation in boreal forest types of southwest Quebec [J]. Canadian Journal of Botany, 2001,79(9):1019-1027.
    [10] Hart S A, Chen H Y H. Understory vegetation dynamics of North American boreal forests [J]. Critical Reviews in Plant Sciences, 2006,25(4):381-397.
    [11] Li Linyuan, Chen Jun, Mu Xihan, et al. Quantifying understory and overstory vegetation cover using UAV-based RGB imagery in forest plantation [J]. Remote Sensing, 2020,12(2):298.
    [12] Wing B M, Ritchie M W, Boston K, et al. Prediction of understory vegetation cover with airborne lidar in an interior ponderosa pine forest [J]. Remote Sensing of Environment, 2012,124:730-741.
    [13] Vartanian M, Nijland W, Coops1 N C, et al. Assessing the impact of field of view on monitoring understory and overstory phenology using digital repeat photography [J]. Canadian Journal of Remote Sensing, 2014,40(2):85-91.
    [14] Hillman S, Wallace L, Reinke K, et al. A method for validating the structural completeness of understory vegetation models captured with 3D remote sensing [J]. Remote Sensing, 2019,11(18):2118.
    [15] Chianucci F, Cutini A, Corona P, et al. Estimation of leaf area index in understory deciduous trees using digital photography [J]. Agricultural and Forest Meteorology, 2014,198:259-264.
    [16] Deng Jiaojiao, Fang Shuai, Fang Xiangmin, et al. Forest understory vegetation study: Current status and future trends [J]. Forestry Research, 2023,3:6.
    [17] Augusto L, Dupouey J L, Ranger J. Effects of tree species on understory vegetation and environmental conditions in temperate forests [J]. Annals of Forest Science, 2003,60(8):823-831.
    [18] Barbier S, Gosselin F, Balandier P. Influence of tree species on understory vegetation diversity and mechanisms involved: A critical review for temperate and boreal forests [J]. Forest Ecology and Management, 2008,254(1):1-15.
    [19] 王惠文,孟洁.多元线性回归的预测建模方法[J].北京航空航天大学学报,2007,33(4):500-504. Wang Huiwen, Meng Jie. Predictive modeling on multivariate linear regression [J]. Journal of Beijing University of Aeronautics and Astronautics, 2007,33(4):500-504.
    [20] Uyanlk G K, Güler N. A study on multiple linear regression analysis [J]. Procedia-Social and Behavioral Sciences, 2013,106:234-240.
    [21] Brereton R G, Lloyd G R. Support vector machines for classification and regression [J]. Analyst, 2010,135(2):230-267.
    [22] 刘勇洪,牛铮,王长耀.基于MODIS数据的决策树分类方法研究与应用[J].遥感学报,2005,9(4):405-412. Liu Yonghong, Niu Zheng, Wang Changyao. Research and application of the decision tree classification using MODIS data [J]. Journal of Remote Sensing, 2005,9(4):405-412.
    [23] 杜续,冯景瑜,吕少卿,等.基于随机森林回归分析的PM2.5浓度预测模型[J].电信科学,2017,33(7):66-75. Du Xu, Feng Jingyu, Lv Shaoqing, et al. PM2.5 concentration prediction model based on random forest regression analysis [J]. Telecommunications Science, 2017,33(7):66-75.
    [24] Smith P F, Ganesh S, Liu Ping. A comparison of random forest regression and multiple linear regression for prediction in neuroscience [J]. Journal of Neuroscience Methods, 2013,220(1):85-91.
    [25] 张文强,罗格平,郑宏伟,等.基于随机森林模型的内陆干旱区植被指数变化与驱动力分析: 以北天山北坡中段为例[J].植物生态学报,2020,44(11):1113-1126. Zhang Wenqiang, Luo Geping, Zheng Hongwei, et al. Analysis of vegetation index changes and driving forces in inland arid areas based on random forest model: A case study of the middle part of northern slope of the North Tianshan Mountains [J]. Chinese Journal of Plant Ecology, 2020,44(11):1113-1126.
    [26] 赵芳,欧阳勋志.飞播马尾松林林下植被盖度与环境因子的关系[J].应用生态学报,2015,26(4):1071-1076. Zhao Fang, Ouyang Xunzhi. Relationships between understory vegetation coverage and environmental factors in Pinus massoniana plantations from aerial seeding [J]. Chinese Journal of Applied Ecology, 2015,26(4):1071-1076.
    [27] 毕馨予,刘晓静,马东来,等.辽宁省植被NDVI对气候因子的滞后响应研究[J].中国农业资源与区划,2021,42(10):233-244. Bi Xinyu, Liu Xiaojing, Ma Donglai, et al. Lag response of vegetation NDVI to climate factors in Liaoning Province [J]. Chinese Journal of Agricultural Resources and Regional Planning, 2021,42(10):233-244.
    [28] 徐凯健,曾宏达,张仲德,等.亚热带福建省森林生长季与气温、降水相关性的遥感分析[J].地球信息科学学报,2015,17(10):1249-1259. Xu Kaijian, Zeng Hongda, Zhang Zhongde, et al. Relating forest phenology to temperature and precipitation in the subtropical region of Fujian based on time-series MODIS-NDVI [J]. Journal of Geo-Information Science, 2015,17(10):1249-1259.
    [29] 马楠,蔡朝朝,白涛.基于机器学习的新疆植被覆盖变化及其影响因子之间的关系[J].湖北农业科学,2024,63(8):216-222. Ma Nan, Cai Zhaozhao, Bai Tao. The relationship between vegetation cover change and its influencing factors in Xinjiang based on machine learning [J]. Hubei Agricultural Sciences, 2024,63(8):216-222.
    [30] Raj D K, Gopikrishnan T. Machine learning models for predicting vegetation conditions in Mahanadi River basin [J]. Environmental Monitoring and Assessment, 2023,195(12):1401.
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赵辉,董世康,杨伟,李璐,余冰.湖北省林下植被盖度时空变化特征及其驱动因素[J].水土保持通报英文版,2025,45(1):82-93

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History
  • Received:September 04,2024
  • Revised:October 25,2024
  • Online: February 22,2025

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