联合星载多光谱影像与机载LiDAR数据的树种小样本分类OA
Small Sample Classification of Tree Species Using Combined Satellite Multispectral Imagery and Airborne LiDAR
[目的]针对树种分类面临的小样本、光谱混淆和跨传感器泛化能力弱等问题,构建自监督对比学习的原型网络,联合星载多光谱与机载 LiDAR高度信息,探究其在小样本条件下及不同传感器间的分类效能和稳健性,为大区域森林资源动态监测提供参考.[方法]基于实地调查数据和 Google Earth高清历史影像标注地类样本,构建包含 3大类 10小类的样本数据集.分别利用 Sentinel-2和 GF-6星载多光谱影像,并引入机载 LiDAR生成的冠层高度模型(CHM)作为扩展波段,应用高度信息增强植被与非植被的区分能力.提出一种集成 CBAM注意力机制和 SimCLR自监督对比学习的改进型原型网络,以增强特征表达能力和小样本学习性能.通过控制变量法评估波段数量和空间分辨率对树种识别的影响,验证分类模型在不同数据集上的泛化性能.[结果]在 Sentinel-2和GF-6数据上的树种分类精度(OA)均超过 85%,在支持集中仅提供少量具有代表性的标注样本就能取得较理想的分类效果,表明本研究模型在小样本条件下的稳健性;注意力机制和自监督策略的引入,使分类精度较基线原型网络提升均超过 2.00%,分类性能显著优于随机森林(RF)和二维卷积神经网络(2D-CNN);跨传感器试验表明,Sentinel-2在光谱区分上更具优势,GF-6凭借 2 m分辨率在边界表征上表现更优,二者分类结果重叠像元比例普遍超过 60%,验证模型良好的跨传感器泛化能力;联合 LiDAR冠 层 高 度 信 息 后,Sentinel-2和 GF-6数据的总体精度分别提升 3.85%和 2.73%,在光谱相似树种上显著缓解了"同谱异物"问题.[结论]星载多光谱影像与 LiDAR数据的联合应用可有效突破传统二维光谱信息分类的局限,改进型原型网络通过注意力机制与对比学习的协同优化,能够显著提升小样本学习效能和跨传感器泛化能力.
[Objective]To address the challenges of small sample sizes,spectral confusion,and weak cross-sensor generalization in tree species classification,a prototype network based on self-supervised contrastive learning was constructed.By integrating satellite-borne multispectral data with airborne LiDAR elevation information,this study aims to explore its classification performance and robustness under small-sample conditions and across different sensors.[Method]Based on field survey data and high-definition historical images from Google Earth,a sample dataset containing 3 major categories and 10 minor categories was constructed.Sentinel-2 and GF-6 satellite multispectral images were utilized respectively,and the airborne LiDAR was introduced to generate canopy height model(CHM)as an extended band,the height information was used to enhance the discrimination ability between vegetation and non-vegetation.An improved prototype network integrating the CBAM attention mechanism and SimCLR self-supervised contrastive learning was proposed to enhance feature representation and small sample learning ability.The control variable method was used to evaluate the impact of the band number and spatial resolution on tree species recognition,and verify the generalization performance of the classification model on different datasets.[Result]The tree species classification accuracy on Sentinel-2 and GF-6 data both exceeded 85%.When the number of samples per category was controlled at 5-10,a relatively ideal classification effect could be achieved,indicating the robustness of the model under small sample conditions.The introduction of attention mechanism and self-supervised strategy improved the classification accuracy by more than 2.00%compared with the baseline prototypical network,and significantly outperformed Random Forest(RF)and two-dimensional convolutional neural networks(2D-CNN).Cross-sensor experiments revealed that Sentinel-2 offered superior spectral discrimination,while GF-6 with its 2 m resolution performed better in boundary delineation.The overlapping ratio of the two classification results generally exceeded 60%,confirming strong cross-sensor generalization ability.After combining LiDAR canopy height information,the overall accuracy(OA)of Sentinel-2 and GF-6 data increased by 3.85%and 2.73%,respectively,effectively alleviating misclassifications among spectrally similar species.[Conclusion]The integration of satellite multispectral imagery and LiDAR data effectively overcomes the limitations of traditional two-dimensional spectral information classification.The improved prototype network significantly enhances small sample learning efficiency and cross-sensor generalization ability through the collaborative optimization of the attention mechanism and contrastive learning,providing a feasible technical path for large-scale forest resource dynamic monitoring.
王嘉豪;谢一帆;葛靖航;王嘉鑫;张晓丽;田昕
北京林业大学林木资源高效生产全国重点实验室 北京 100083||北京林业大学精准林业北京市重点实验室 北京 100083||北京林业大学森林培育与保护教育部重点实验室 北京 100083北京林业大学林木资源高效生产全国重点实验室 北京 100083||北京林业大学精准林业北京市重点实验室 北京 100083||北京林业大学森林培育与保护教育部重点实验室 北京 100083北京林业大学林木资源高效生产全国重点实验室 北京 100083||北京林业大学精准林业北京市重点实验室 北京 100083||北京林业大学森林培育与保护教育部重点实验室 北京 100083北京林业大学林木资源高效生产全国重点实验室 北京 100083||北京林业大学精准林业北京市重点实验室 北京 100083||北京林业大学森林培育与保护教育部重点实验室 北京 100083北京林业大学林木资源高效生产全国重点实验室 北京 100083||北京林业大学精准林业北京市重点实验室 北京 100083||北京林业大学森林培育与保护教育部重点实验室 北京 100083中国林业科学研究院资源信息研究所 北京 100091
生物科学
树种分类小样本注意力机制自监督对比学习冠层高度信息
tree species classificationsmall sampleattention mechanismself-supervised contrastive learningcanopy height model
《林业科学》 2026 (5)
80-95,16
天空地一体化森林资源监测技术示范(2023YFD2201700)中欧对地观测合作森林监测技术与示范应用(2021YFE0117700).
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