基于机器学习算法的扬州市冬小麦遥感分类提取

doi:10.13733/j.jcam.issn.2095‑5553.2024.08.023

摘要/Abstract

摘要： 卫星遥感技术是目前较为常用的农作物监测与分类技术。为实现区域冬小麦精确分类和面积提取，以江苏省扬州市为例，以哨兵2号卫星数据及航天飞机雷达地形测量（SRTM）高程数据为数据源，利用分类与回归决策树（CART）、梯度提升决策树（GBDT）、支持向量机（SVM）和随机森林（RF）4种机器学习算法建立分类模型。同时下载并调用2021年3月22日研究区的MSI多光谱影像，提取光谱、纹理、地形特征等参数，对研究区冬小麦进行分类提取，并分析4种模型的分类效果和精度。结果表明，RF和GBDT分类方法效果最好，总体精度最高，均为0.967，Kappa系数达0.960；SVM分类方法总体精度最低，为0.514，但用户精度最高，为0.972。上述方法可以实现区域农作物的精确分类和提取。

关键词: 冬小麦, 机器学习, 单时相, 面积提取, 遥感分类

Abstract: Satellite remote sensing technology is a commonly used monitoring and classification technology in crops at present. In order to achieve accurate classification and area extraction of regional winter wheat, Yangzhou City, Jiangsu Province had been taken as an example in this study. The Sentinel-2 satellite data and Shuttle Radar Topography Mission (SRTM) elevation data were used as data sources. Four machine learning algorithms, including classification and regression decision tree (CART), Gradient Boosted Decision Tree (GBDT), support vector machine (SVM) and Random forests (RF), were used to establish the classification model. At the same time, the MSI multispectral image of March 22, 2021 in the study area was called and downloaded to extract parameters such as spectrum, texture and terrain features, and the winter wheat in the study area was classified and extracted, and the classification effect and accuracy of the four models were analyzed. The results showed that RF and GBDT classification methods had the best effect and the highest overall accuracy (OA), and both of the OA values were 0.967 and Kappa coefficient was 0.960. The OA of SVM classification method was the lowest (0.514), but the user accuracy (UA) was the highest (0.972). The method mentioned above could realize accurate classification and extraction of regional crops.

Key words: winter wheat, machine learning, single temporal, area extraction, remote sensing classification

中图分类号:

TP79
S512

陈雨欣, 刘章鑫, 刘欣谊, 刘涛, 孙成明, . 基于机器学习算法的扬州市冬小麦遥感分类提取[J]. 中国农机化学报, 2024, 45(8): 154-161.

Chen Yuxin, , Liu Zhangxin, , Liu Xinyi, , Liu Tao, , Sun Chengming, , . Remote sensing classification and extraction of winter wheat in Yangzhou based on machine learning algorithm[J]. Journal of Chinese Agricultural Mechanization, 2024, 45(8): 154-161.

参考文献

[ 1 ] 王利民，刘佳，杨福刚，等. 基于GF-1卫星遥感数据识别京津冀冬小麦面积[J]. 作物学报， 2018， 44（5）: 762-773.
Wang Limin， Liu Jia， Yang Fugang， et.al. Acguisition of winter wheat area in the Beijing‑Tianjin‑Hebei region with GF-1 satellite data [J]. Acta Agronomica Sinica， 2018， 44（5）: 762-773.
[ 2 ] Zeyada， Ezz， Nasr， et al. Evaluation of the discrimination capability of full polarimetric SAR data for crop classification [J]. International Journal of Remote Sensing， 2016， 37（11）: 2585-2603.
[ 3 ] 杨伟，方涛，许刚. 基于朴素贝叶斯的半监督学习遥感影像分类[J]. 计算机工程， 2010， 36（20）: 167-169.
Yang Wei， Fang Tao， Xu Gang. Semi‑supervised learning remote sensing image classification based on Naïve Bayesian [J]. Computer Engineering， 2010， 36（20）: 167-169.
[ 4 ] 蒋治浩，林辉，张怀清，等. 面向对象结合卷积神经网络的GF-1影像遥感分类[J]. 中南林业科技大学学报， 2021， 41（8）: 45-55.
Jiang Zhaihao， Lin Hui， Zhang Huaiqing， et al. Remote sensing image of GF-1 classification using object‑oriented method and convolutional neural network [J]. Journal of Central South University of Forestry & Technology， 2021， 41（8）: 45-55.
[ 5 ] 孙庆松. 基于Sentinel数据的县域尺度农作物分类研究[D]. 邯郸: 河北工程大学， 2021.
[ 6 ] Chi M M， Bruzzone L. Semisupervised classification of hyperspectral images by SVMs optimized in the primal [J]. IEEE Transactions on Geoscience and Remote Sensing， 2007， 45（6）: 1870-1880.
[ 7 ] Rutkowski L， Jaworski M， Pietruczuk L， et al. The CART decision tree for mining data streams [J]. Information Sciences， 2014， 266: 1-15.
[ 8 ] 陈雨桐. 集成学习算法之随机森林与梯度提升决策树的分析比较[J]. 电脑知识与技术， 2021， 17（15）: 32-34.
Chen Yutong. Analysis and comparison of stochastic forest and gradient lifting decision tree for ensemble learning algorithms [J]. Computer Knowledge and Technology， 2021， 17（15）: 32-34.
[ 9 ] Mahlein A K， Rumpf T， Welke P， et al. Development of spectral indices for detecting and identifying plant diseases [J]. Remote Sensing of Environment， 2013， 128: 21-30.
[10] Gao B. NDWI-A normalized difference water index for remote sensing of vegetation liquid water from space [J]. Remote Sensing of Environment， 1996， 58（3）: 257-266.
[11] 查勇，倪绍祥，杨山. 一种利用TM图像自动提取城镇用地信息的有效方法[J]. 遥感学报， 2003（1）: 37-40.
Zha Yong， Ni Shaoxiang， Yang Shan. An effective method for automatic extraction of urban land use information using TM image [J]. Journal of Remote Sensing， 2003（1）: 37-40.

[1]	潘健, 祁雁楠, 陈鲁威, 夏烨, 吕晓兰, . 基于可见/近红外高光谱成像技术的梨树叶部病害识别研究[J]. 中国农机化学报, 2024, 45(8): 162-169.
[2]	张倩, 王明, 于峰, 陶震宇, 张辉, 李刚. 基于CNN的作物分类识别图像获取平台研究进展[J]. 中国农机化学报, 2024, 45(8): 170-179.
[3]	唐可记, 孙文磊, 杨炀, 孔德龙. 玉米收获机发动机服役状态趋势分析与预警[J]. 中国农机化学报, 2024, 45(7): 160-165.
[4]	马志艳, , 李辉, 杨光友, . 基于YOLOv3算法的智能采茶机关键技术研究[J]. 中国农机化学报, 2024, 45(4): 199-204.
[5]	陈鲁威, , 曾锦, , 袁全春, , 潘健, , 姚凤腾, , 吕晓兰, . 无人机遥感监测果树氮素含量研究进展[J]. 中国农机化学报, 2024, 45(2): 235-243.
[6]	王春桃, , , , 梁炜健, 郭庆文, 钟浩, 甘雨, 肖德琴, , . 农业害虫智能视觉检测研究综述[J]. 中国农机化学报, 2023, 44(7): 207-213.
[7]	徐衍向, 张敬智, 兰玉彬, , 孙越梅, 韩鑫, 白京波. 于红外热成像和机器学习的作物早期病害识别研究进展[J]. 中国农机化学报, 2023, 44(5): 188-197.
[8]	孜尼哈尔·祖努尼江, , 尼加提·卡斯木, , 拓跋凯薇. 基于FOD-ML的干旱区土壤有机质含量估算[J]. 中国农机化学报, 2023, 44(11): 201-209.
[9]	邬粒, 邹黎敏, 周科. 基于机器学习的重庆市粮食产量预测及影响因素分析[J]. 中国农机化学报, 2023, 44(10): 185-193.
[10]	孙逸飞, 柳平增, 张艳, 宋长青, 张大雷, 马学文. 基于Sentinel-2A遥感影像的潍坊市冬小麦种植面积提取研究[J]. 中国农机化学报, 2022, 43(7): 98-105.
[11]	王聪;姜舒文;黄坤;邵小东;杨启凡;陈天恩;. 机器学习在农产品供应链关键环节中的应用进展研究综述[J]. 中国农机化学报, 2021, 42(5): 182-190.
[12]	谢英杰;王国宾;王宝聚;单常峰;兰玉彬;. 植保无人机喷施除草剂喷头选择及参数优化[J]. 中国农机化学报, 2021, 42(4): 61-69.
[13]	李健;熊琦;胡雅婷;. 基于改进AdaBoost算法对环柄菇毒性判别研究[J]. 中国农机化学报, 2021, 42(3): 72-77.
[14]	王宝聚, 兰玉彬, 陈蒙蒙, 柳宝虎, 王国宾, 刘海涛, . 机器学习在无人农场中的应用现状与展望[J]. 中国农机化学报, 2021, 42(10): 186-192+217.
[15]	王聃;柴秀娟;. 机器学习在植物病害识别研究中的应用[J]. 中国农机化学报, 2019, 40(9): 171-180.