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将PROSPECT-D物理学与对抗域适应残差网络相结合,用于稳健的跨生态系统植物性状估计。

Integrating PROSPECT-D physics and adversarial domain adaptation resnet for robust cross-ecosystem plant traits estimation.

作者信息

Zhang Hui, Su Haoxuan, Shen Tie, Sun Guangyao, Wang Qi

机构信息

School of Information, Guizhou University of Finance and Economics, Guiyang, China.

Guizhou Provincial Leading Talent Workstation for Protein Design and Biological Imaging Innovation, Key Laboratory of National Forestry and Grassland Administration on Biodiversity Conservation in Karst Mountainous Areas of Southwestern China, College of Life Science, Guizhou Normal University, Guiyang, China.

出版信息

Front Plant Sci. 2025 Jul 25;16:1612430. doi: 10.3389/fpls.2025.1612430. eCollection 2025.

DOI:10.3389/fpls.2025.1612430
PMID:40786948
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12331702/
Abstract

Plant functional traits, including chlorophyll content (CHL), equivalent water thickness (EWT), and leaf mass per area (LMA), are critical indicators for assessing ecosystem functioning, functional diversity, and their roles in the Earth system. Hyperspectral remote sensing serves as a pivotal tool for multi-trait mapping; however, existing methods exhibit limited generalizability across ecosystems, land cover types, and sensor modalities. Challenges such as data heterogeneity, domain shifts, and sparse measurements further hinder model generalization. To address these limitations, this study developed PPADA-Net, a novel framework integrating PROSPECT-D radiative transfer modeling with adversarial domain adaptation for robust cross-ecosystem plant trait prediction. In a two-stage process, a residual network is pretrained on synthetic spectra from PROSPECT-D to capture biophysical links between leaf traits and spectral signatures, followed by adversarial learning to align source and target domain features, reducing domain shifts. The model's performance is validated on four public datasets and one field-measured dataset. PPADA-Net outperforms traditional partial least squares regression (PLSR) and purely data-driven models (e.g., ResNet), achieving mean R² values of 0.72 (CHL),0.77 (EWT), and 0.86 (LMA). Additionally, PPADA-Net demonstrates practical utility in a real-world farmland dataset (D5), achieving high-precision spatial mapping with an nRMSE of 0.07 for LMA. By merging physical priors with adaptive learning, PPADA-Net enhances spectral-trait modeling under data scarcity, offering a scalable tool for ecosystem monitoring, precision agriculture, and climate adaptation.

摘要

植物功能性状,包括叶绿素含量(CHL)、等效水厚度(EWT)和单位面积叶质量(LMA),是评估生态系统功能、功能多样性及其在地球系统中作用的关键指标。高光谱遥感是多性状制图的关键工具;然而,现有方法在不同生态系统、土地覆盖类型和传感器模式下的通用性有限。数据异质性、域转移和稀疏测量等挑战进一步阻碍了模型的泛化。为了解决这些局限性,本研究开发了PPADA-Net,这是一个将PROSPECT-D辐射传输模型与对抗域适应相结合的新颖框架,用于稳健的跨生态系统植物性状预测。在一个两阶段过程中,首先在来自PROSPECT-D的合成光谱上预训练一个残差网络,以捕捉叶片性状与光谱特征之间的生物物理联系,然后进行对抗学习以对齐源域和目标域特征,减少域转移。该模型的性能在四个公共数据集和一个实地测量数据集上得到验证。PPADA-Net优于传统的偏最小二乘回归(PLSR)和纯数据驱动模型(如ResNet),CHL、EWT和LMA的平均R²值分别达到0.72、0.77和0.86。此外,PPADA-Net在一个实际农田数据集(D5)中展示了实用价值,LMA的nRMSE为0.07,实现了高精度的空间制图。通过将物理先验与自适应学习相结合,PPADA-Net在数据稀缺的情况下增强了光谱-性状建模,为生态系统监测、精准农业和气候适应提供了一个可扩展的工具。

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