Leveraging transfer learning and leaf spectroscopy for leaf trait prediction with broad spatial, species, and temporal applicability

IF 11.4 1区地球科学 Q1 ENVIRONMENTAL SCIENCES

Remote Sensing of Environment Pub Date : 2025-05-20 DOI:10.1016/j.rse.2025.114818

Fujiang Ji , Fa Li , Hamid Dashti , Dalei Hao , Philip A. Townsend , Ting Zheng , Hangkai You , Min Chen

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引用次数: 0

Abstract

Accurate and reliable prediction of leaf traits is crucial for understanding plant adaptations to environmental variation, monitoring terrestrial ecosystems, and enhancing comprehension of functional diversity and ecosystem functioning. Currently, various approaches (e.g., statistical, physical models) have been developed to estimate leaf traits through hyperspectral remote sensing and leaf spectroscopy. However, the absence of high-performing, transferable, and stable models across various domains of space, plant functional types (PFTs) and seasons hinder our ability to quantify and comprehend spatiotemporal variations in leaf traits. This study proposes robust and highly transferable models for better predicting leaf traits with hyperspectral reflectance. Initially, three datasets were assembled, pairing common leaf traits — chlorophyll (Chla+b), carotenoids (Ccar), leaf mass per area (LAM), equivalent water thickness (EWT) — with leaf spectra measurements collected across diverse geographic locations in the U.S. and Europe, PFTs, and seasons. Measurements were acquired using spectroradiometers (e.g., ASD FieldSpec 3/4/Pro and SVC HR-1024i) with integrating spheres, leaf clips, and contact probes. We then developed transfer learning-based hybrid models that incorporated the domain knowledge of radiative transfer models (RTMs) through pretraining processes and were well-constrained by fine-tuning with field measurements. Through comparison with other state-of-the-art statistical models, including partial-least squares regression (PLSR) and Gaussian Process Regression (GPR), as well as pure physical models, we found that the proposed transfer learning models achieved better predictive performance and higher transferability. Specifically, compared to other statistical models and pure RTMs, the transfer learning model exhibited higher coefficient of determination (R²) values with range of 0.01 to 0.79, lower normalized root mean square error (NRMSE) with range of 0.06 % to 33.25 % in model performance. Additionally, the models exhibited improved transferability, with higher R² values range from 0.04 to 0.32, lower NRMSE range from 0.08 % to 30.81 %. The findings underscore that transfer learning models through integrating domain knowledge from RTMs and limited observations, can harness the advantages of both RTMs and statistical models and serve as a promising approach for effectively predicting leaf traits.

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利用迁移学习和叶片光谱学进行叶片性状预测，具有广泛的空间、物种和时间适用性

准确、可靠的叶片性状预测对于了解植物对环境变化的适应、监测陆地生态系统、提高对功能多样性和生态系统功能的认识具有重要意义。目前，利用高光谱遥感和叶片光谱学估算叶片性状的方法有统计模型、物理模型等。然而，缺乏跨空间、植物功能类型和季节的高效、可转移和稳定的模型，阻碍了我们量化和理解叶片性状时空变化的能力。本研究提出了稳健且高度可转移的模型，以更好地预测叶片的高光谱反射率特征。最初，收集了三个数据集，将常见的叶片特征-叶绿素（Chla+b），类胡萝卜素（Ccar），每面积叶质量（LAM），等效水厚(EWT) -与在美国和欧洲不同地理位置，PFTs和季节收集的叶片光谱测量相匹配。测量使用光谱辐射计（例如，ASD FieldSpec 3/4/Pro和SVC HR-1024i），集成球体，叶片夹和接触探头。然后，我们开发了基于迁移学习的混合模型，该模型通过预训练过程结合了辐射迁移模型（RTMs）的领域知识，并通过现场测量进行微调。通过与其他最先进的统计模型，包括偏最小二乘回归（PLSR）和高斯过程回归（GPR）以及纯物理模型的比较，我们发现所提出的迁移学习模型具有更好的预测性能和更高的可迁移性。具体而言，与其他统计模型和纯RTMs相比，迁移学习模型在模型性能上表现出更高的决定系数（R2）值，范围为0.01 ~ 0.79，更低的归一化均方根误差（NRMSE），范围为0.06% ~ 33.25%。模型具有较好的可转移性，较高的R2值为0.04 ~ 0.32，较低的NRMSE值为0.08% ~ 30.81%。研究结果表明，通过整合rtm的领域知识和有限的观测数据，迁移学习模型可以利用rtm和统计模型的优势，为有效预测叶片性状提供了一种有前途的方法。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Remote Sensing of Environment 环境科学-成像科学与照相技术

CiteScore

25.10

自引率

8.90%

发文量

455

审稿时长

53 days

期刊介绍： Remote Sensing of Environment (RSE) serves the Earth observation community by disseminating results on the theory, science, applications, and technology that contribute to advancing the field of remote sensing. With a thoroughly interdisciplinary approach, RSE encompasses terrestrial, oceanic, and atmospheric sensing. The journal emphasizes biophysical and quantitative approaches to remote sensing at local to global scales, covering a diverse range of applications and techniques. RSE serves as a vital platform for the exchange of knowledge and advancements in the dynamic field of remote sensing.