基于无人机多光谱数据的柑橘叶面积指数反演

doi:10.14088/j.cnki.issn0439-8114.2025.08.004

湖北农业科学 ›› 2025, Vol. 64 ›› Issue (8): 24-30.doi: 10.14088/j.cnki.issn0439-8114.2025.08.004

基于无人机多光谱数据的柑橘叶面积指数反演

陈治宇¹, 窦世卿²

1.贵阳职业技术学院城乡规划建设分院,贵阳 550081;
2.桂林理工大学测绘地理信息学院,广西桂林 541006

收稿日期:2025-05-20 出版日期:2025-08-25 发布日期:2025-09-12
通讯作者: 窦世卿(1977-),女,河北定州人,教授,博士,主要从事三维GIS与遥感技术应用研究,（电话）15104536271（电子信箱）doushiqing@glut.edu.cn。
作者简介:陈治宇(1994-),男,贵州贵阳人,硕士,主要从事农业遥感研究,（电话）13984326128（电子信箱）1014300283@qq.com;

UAV multispectral data-based leaf area index retrieval for citrus

CHEN Zhi-yu¹, DOU Shi-qing²

1. School of Urban-Rural Planning and Construction, Guiyang Vocational and Technical College, Guiyang 550081, China;
2. College of Geomatics and Geoinformation, Guilin University of Technology, Guilin 541006, Guangxi, China

Received:2025-05-20 Published:2025-08-25 Online:2025-09-12

摘要/Abstract

摘要： 以柑橘(Citrus reticulata)为研究对象,采集无人机多光谱与柑橘叶面积指数(LAI)数据,对多光谱数据进行波段选择和组合后,采用Boruta算法、RFECV方法及未筛选3种特征处理方式,分别结合向量回归(SVR)、随机森林回归(RFR)、BP神经网络(BPNNR) 3种机器学习回归模型构建9种LAI估测组合模型。使用GridSearchCV方法优化模型参数后,对比各模型的精度和稳定性,选出最优LAI预测模型,并生成柑橘LAI空间分布影像。结果表明,Boruta算法可以有效筛选特征变量、降低模型的过拟合程度;在9种组合模型中,Boruta_BPNNR模型在柑橘LAI估测中表现最优,其数据离散度小,回归曲线与对角线的拟合度高。LAI反演结果表明,研究区LAI空间分布呈明显的南北梯度差异,北部地区的LAI普遍高于南部地区,这与实地调查中北部地区柑橘生长繁茂、南部地区长势相对稀疏的空间格局基本一致。

关键词: 柑橘(Citrus reticulata), 无人机多光谱, 叶面积指数(LAI), Boruta_BPNNR模型, 反演

Abstract: Citrus (Citrus reticulata) was selected as the research object, and UAV multispectral data and citrus leaf area index (LAI) data were collected. After band selection and combination of the multispectral data, three feature processing approaches (Boruta algorithm, RFECV method, and no feature selection) were employed, each combined with three machine learning regression models (support vector regression (SVR), random forest regression (RFR), and backpropagation neural network regression (BPNNR)) to construct nine combined models for LAI estimation. The model parameters were optimized using the GridSearchCV method, the accuracy and stability of each model were compared, the optimal LAI prediction model was selected, and a spatial distribution image of citrus LAI was generated. The results showed that the Boruta algorithm could effectively select feature variables and reduce model overfitting. Among the nine combined models, the Boruta_BPNNR model performed best in citrus LAI estimation, exhibiting low data dispersion and a high degree of fit between the regression curve and the diagonal line. The LAI retrieval results indicated that the spatial distribution of LAI in the study area showed a distinct north-south gradient difference, with LAI generally higher in the northern region than in the southern region. This was basically consistent with the spatial pattern observed in the field survey, where citrus growth was lush in the north region and relatively sparse in the south region.

Key words: citrus (Citrus reticulata), UAV multispectral, leaf area index (LAI), Boruta_BPNNR model, retrieval

中图分类号:

S123
S666

陈治宇, 窦世卿. 基于无人机多光谱数据的柑橘叶面积指数反演[J]. 湖北农业科学, 2025, 64(8): 24-30.

CHEN Zhi-yu, DOU Shi-qing. UAV multispectral data-based leaf area index retrieval for citrus[J]. HUBEI AGRICULTURAL SCIENCES, 2025, 64(8): 24-30.

参考文献

[1] 刘霞, 周凌霄, 夏心杰, 等. 基于混合蝙蝠智能算法优化PLSR的柑橘叶片氮含量预测方法[J]. 西南大学学报(自然科学版), 2025,47(2):160-170.
[2] 汪彦龙, 王钧, 李广, 等. 采用机器学习优化PROSAIL模型的青贮玉米叶面积指数反演[J]. 农业工程学报,2025,41(9):134-142.
[3] 齐浩, 孙海芳, 吕亮杰, 等. 基于无人机多光谱信息与纹理特征融合的小麦叶面积指数估测[J]. 农业机械学报,2025,56(3):334-344.
[4] 王军, 姜芸. 基于无人机多光谱遥感的大豆叶面积指数反演[J]. 中国农学通报, 2021,37(19):134-142.
[5] 向友珍, 王辛, 安嘉琪, 等. 基于分数阶微分和最优光谱指数的大豆叶面积指数估算[J]. 农业机械学报, 2023,54(9):329-342.
[6] 刘昕哲, 武璐, 陈李金, 等. 基于半经验半机理建模的冬小麦LAI反演及长势评估[J]. 农业工程学报, 2024,40(1):162-170.
[7] 余兴娇, 樊凯, 霍雪飞, 等. 基于无人机影像多特征融合的夏玉米LAI动态估计[J]. 农业工程学报, 2025,41(4):124-134.
[8] 张宏鸣, 刘雯, 韩文霆, 等. 基于梯度提升树算法的夏玉米叶面积指数反演[J]. 农业机械学报, 2019,50(5):251-259.
[9] 周恺, 周彤, 丁峰, 等. 基于无人机图像的小麦主要生育时期LAI估算[J]. 中国农业科技导报, 2021,23(1):89-97.
[10] 冯志立, 肖锋, 卢小平, 等. 基于随机森林特征优选的冬小麦分类方法[J]. 测绘通报, 2022(3):70-75.
[11] SECHIDIS K, AZZIMONTI L, POCOCK A,et al.Efficient feature selection using shrinkage estimators[J].Machine learning, 2019, 108(8):1261-1286
[12] DEGENHARDT F,SEIFERT S,SZYMCZAK S.Evaluation of variable selection methods for random forests and omics data sets[J]. Briefings in bioinformatics, 2019,20(2):492-503.
[13] AGJEE N H,ISMAIL R, MUTANGA O.Identifying relevant hyperspectral bands using Boruta: A temporal analysis of water hyacinth biocontrol[J].Journal of applied remote sensing, 2016, 10(4):042002.
[14] 卢宏亮,赵明松,刘斌寅,等. 基于Boruta-支持向量回归的安徽省土壤pH值预测制图[J]. 地理与地理信息科学,2019,35(5):66-72.
[15] 韩瑞, 吴达胜, 方陆明, 等. 基于Boruta和极端随机树方法的森林蓄积量估测[J]. 林业资源管理, 2020(4):127-133.
[16] 安宇, 陈桂芬, 李静. 基于递归特征消除和随机森林融合算法的大豆前体MicroRNA预测模型研究[J]. 大豆科学, 2020,39(3):401-405.
[17] ROUJEAN J L, BREON F M.Estimating PAR absorbed by vegetation from bidirectional reflectance measurements[J].Remote sensing of environment, 1995, 51(3):375-384.
[18] CHEN J M.Evaluation of vegetation indices and a modified simple ratio for boreal applications[J]. Canadian journal of remote sensing, 2014,22(3):229-242.
[19] CAO Q, MIAO Y, WANG H, et al.Non-destructive estimation of rice plant nitrogen status with crop circle multispectral active canopy sensor[J]. Field crops research, 2013,154:133-144.
[20] GOEL N S, QIN W.Influences of canopy architecture on relationships between various vegetation indices and LAI and Fpar: A computer simulation[J].Remote sensing reviews, 1994, 10(4):309-347.
[21] RONDEAUX G, STEVEN M, BARET F.Optimization of soil-adjusted vegetation indices[J]. Remote sensing of environment, 1996,55(2):95-107.
[22] REYNIERS M, WALVOORT D J J, DE BAARDEMAAKER J. A linear model to predict with a multi-spectral radiometer the amount of nitrogen in winter wheat[J]. International journal of remote sensing, 2006,27(19):4159-4179.
[23] 徐洪刚, 陈震, 程千, 等. 无人机多源光谱反演大田夏玉米叶面积指数[J]. 灌溉排水学报, 2021,40(8):42-49.
[24] GITELSON A A.Wide dynamic range vegetation index for remote quantification of biophysical characteristics of vegetation[J]. Journal of plant physiology, 2004,161(2):165-173.
[25] LU J, MIAO Y, SHI W, et al.Evaluating different approaches to non-destructive nitrogen status diagnosis of rice using portable RapidSCAN active canopy sensor[J]. Scientific reports, 2017, 7(1):14010-14073.
[26] SRIPADA R P, HEINIGER R W, WHITE J G, et al.Aerial color infrared photography for determining early in-season nitrogen requirements in corn[J]. Agronomy journal, 2006,98(4):968-977.
[27] 刘珺, 庞鑫, 李彦荣, 等. 夏玉米叶面积指数遥感反演研究[J]. 农业机械学报, 2016,47(9):309-317.
[28] 张矞勋,齐拓野, 孙源, 等. 高分六号遥感影像植被特征及其在冬小麦苗期LAI反演中的应用[J]. 作物学报,2021,47(12):2532-2540.
[29] GITELSON A A, MERZLYAK M N, CHIVKUNOVA O B.Optical properties and nondestructive estimation of anthocyanin content in plant leaves[J]. Photochem photobiol, 2001,74(1):38-45.
[30] 孔钰如, 王李娟, 冯海宽, 等. 无人机高光谱波段选择的叶面积指数反演[J]. 光谱学与光谱分析, 2022,42(3):933-939.
[31] 邢晓语,杨秀春, 徐斌, 等. 基于随机森林算法的草原地上生物量遥感估算方法研究[J]. 地球信息科学学报, 2021,23(7):1312-1324.
[32] 赵建辉,张晨阳,闵林,等. 基于特征选择和GA-BP神经网络的多源遥感农田土壤水分反演[J]. 农业工程学报,2021,37(11):112-120.

基于无人机多光谱数据的柑橘叶面积指数反演

UAV multispectral data-based leaf area index retrieval for citrus

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 7

编辑推荐

Metrics

本文评价

[1]	班若楠, 董峦. 基于深度学习的盐碱地遥感影像反演模型构建[J]. 湖北农业科学, 2025, 64(6): 185-189.
[2]	王宦臣, 张吴平, 李富忠. 复合种植方式下大豆和玉米株高的动态反演[J]. 湖北农业科学, 2024, 63(8): 231-235.
[3]	王莹, 李重庆, 刘清圣, 卢麒麟. 云南红壤水力参数差异较大的原因探究[J]. 湖北农业科学, 2024, 63(12): 24-30.
[4]	刘宇, 朱丹瑶. 基于Landsat 8 OLI数据的镜泊湖水体叶绿素a浓度反演[J]. 湖北农业科学, 2021, 60(23): 157-162.
[5]	刘宇. 镜泊湖水体富营养化空间分布特征与影响因素分析[J]. 湖北农业科学, 2020, 59(5): 54-56.
[6]	张仙, 胡西洲, 彭西甜, 王小飞. QuEChERS-气相色谱法测定柑橘皮中19种有机磷农药残留[J]. 湖北农业科学, 2020, 59(21): 147-150.
[7]	刘琳, 陈红, 李磊, 彭帅, 刘艺璇. 基于机械损伤的宽皮柑橘贮藏期间力学特性研究[J]. 湖北农业科学, 2019, 58(15): 124-127.