Visible-near infrared hyperspectral imaging for non-destructive estimation of leaf nitrogen content under water-saving irrigation in protected tomato cultivation.

IF 4.1 2区生物学 Q1 PLANT SCIENCES

Frontiers in Plant Science Pub Date : 2025-10-01 eCollection Date: 2025-01-01 DOI:10.3389/fpls.2025.1676457

Caixia Hu, Tingting Zhao, Yingying Duan, Yungui Zhang, Xinxiu Wang, Jie Li, Guilong Zhang

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引用次数: 0

Abstract

Accurate estimation of leaf nitrogen content (LNC) is critical for optimizing fertilization strategies in greenhouse tomato production. This study developed a robust hyperspectral-based framework for non-destructive LNC prediction by combining advanced spectral preprocessing, feature selection, and machine learning. Hyperspectral reflectance data were collected across five nitrogen and irrigation treatments over key growth stages. Signal quality was enhanced through Savitzky-Golay smoothing (SG) and Standard Normal Variate normalization (SNV). Key nitrogen-sensitive wavelengths-centered around 725 nm and 730 - 780 nm-were identified using Competitive Adaptive Reweighted Sampling (CARS) and Principal Component Analysis (PCA). Four predictive models were compared, among which a hybrid Stacked Autoencoder-Feedforward Neural Network (SAE-FNN) achieved the highest accuracy (test R² = 0.77, RPD = 2.06), effectively capturing nonlinear spectral-nitrogen interactions. In contrast, Support Vector Machine (SVM) exhibited overfitting and Partial Least Squares Method (PLSR) underperformed due to its linear constraints. These results underscore the potential of integrating hyperspectral sensing with deep learning for intelligent nitrogen monitoring in controlled-environment agriculture.

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利用可见-近红外高光谱成像技术无损估算番茄节水灌溉条件下叶片氮含量。

叶片氮含量的准确估算是优化温室番茄施肥策略的关键。本研究通过结合先进的光谱预处理、特征选择和机器学习，开发了一个鲁棒的基于高光谱的非破坏性LNC预测框架。高光谱反射率数据收集了5个氮肥处理和灌溉处理在关键生长阶段的数据。通过Savitzky-Golay平滑（SG）和标准正态变量归一化（SNV）增强信号质量。利用竞争自适应重加权采样（CARS）和主成分分析（PCA）确定了725 nm和730 - 780 nm附近的关键氮敏感波长。对比了4种预测模型，其中SAE-FNN （Stacked Autoencoder-Feedforward Neural Network）的预测精度最高（检验R²= 0.77,RPD = 2.06），能有效捕获非线性光谱-氮相互作用。相比之下，支持向量机（SVM）由于其线性约束而表现出过拟合和偏最小二乘法（PLSR）表现不佳。这些结果强调了将高光谱传感与深度学习相结合用于受控环境农业智能氮监测的潜力。

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

Frontiers in Plant Science PLANT SCIENCES-

CiteScore

7.30

自引率

14.30%

发文量

4844

审稿时长

14 weeks

期刊介绍： In an ever changing world, plant science is of the utmost importance for securing the future well-being of humankind. Plants provide oxygen, food, feed, fibers, and building materials. In addition, they are a diverse source of industrial and pharmaceutical chemicals. Plants are centrally important to the health of ecosystems, and their understanding is critical for learning how to manage and maintain a sustainable biosphere. Plant science is extremely interdisciplinary, reaching from agricultural science to paleobotany, and molecular physiology to ecology. It uses the latest developments in computer science, optics, molecular biology and genomics to address challenges in model systems, agricultural crops, and ecosystems. Plant science research inquires into the form, function, development, diversity, reproduction, evolution and uses of both higher and lower plants and their interactions with other organisms throughout the biosphere. Frontiers in Plant Science welcomes outstanding contributions in any field of plant science from basic to applied research, from organismal to molecular studies, from single plant analysis to studies of populations and whole ecosystems, and from molecular to biophysical to computational approaches. Frontiers in Plant Science publishes articles on the most outstanding discoveries across a wide research spectrum of Plant Science. The mission of Frontiers in Plant Science is to bring all relevant Plant Science areas together on a single platform.