Developing a Hyperspectral Remote Sensing-Based Algorithm to Diagnose Potato Moisture for Water-Saving Irrigation
-
Published:2024-07-31
Issue:8
Volume:10
Page:811
-
ISSN:2311-7524
-
Container-title:Horticulturae
-
language:en
-
Short-container-title:Horticulturae
Author:
Suyala Qiqige12, Li Zhuoling1, Zhang Zhenxin3, Jia Liguo3, Fan Mingshou3, Sun Youping4, Xing Haifeng12
Affiliation:
1. College of Grassland and Resource Environment, Inner Mongolia Agricultural University, Hohhot 010019, China 2. Key Laboratory of Agricultural Ecological Security and Green Development at Universities of Inner Mongolia Autonomous, Hohhot 010018, China 3. College of Agronomy, Inner Mongolia Agricultural University, Hohhot 010018, China 4. Department of Plants, Soils & Climate, Utah State University, Logan, UT 84322, USA
Abstract
Appropriate water supply is crucial for high-yield and high-quality potato tuber production. However, potatoes are mainly planted in arid and semi-arid regions in China, where the precipitation usually cannot meet the water demand throughout the growth period. In view of the actual situation of water shortage in these areas, to monitor the water status of potato plants timely and accurately and thus precisely control the irrigation are of significance for water-saving management of potatoes. Hyperspectral remote sensing has unique advantages in diagnosing crop water stress. In this paper, the canopy spectral reflectance and plant water content were measured under five irrigation treatments. The spectral parameters that respond to plant water content were selected, and a hyperspectral water diagnosis model for leaf water content (LWC) and aboveground water content (AGWC) of potato plants was established. It was found that potato tuber yield was the highest during the entire growth period under sufficient irrigation, and the plant water content showed a downward trend as the degree of drought intensified. The peak hyperspectral reflectance of potato plant canopies appeared in the red wavelength, where the reflectance varied significantly under different water treatments and decreased with decreasing irrigation. Six models with sensitive bands, first-order derivatives, and moisture spectral indices were established to monitor water content of potato plants. The R2 values of partial least squares regression (PLSR), support vector machine (SVM), and BP neural network (BP) models are 0.8418, 0.9020, and 0.8926, respectively, between LWC and hyperspectral data; and 0.8003, 0.8167, and 0.8671, respectively, between the AGWC and hyperspectral data. These six models can all predict the water content of potato plants, but SVM is the best model for predicting LWC of potato plants. These results are of great significance for guiding precision irrigation of potato plants at different growth stages.
Funder
National Natural Science Foundation of China Natural Science Foundation of Inner Mongolia Science and Technology Planning Project of Inner Mongolia research start-up funds of IMAU
Reference43 articles.
1. (2024, March 21). Available online: http://www.fao.org/faostat/en/#data/QCL. 2. Luo, Q., Gao, M., Liu, Z., Lu, H., and Zhang, S. (2021). Analysis on the development situation of Chinese potato industry in 2020. Malingshu Chanye Yu Lvse Fazhan, Proceedings of the 23rd China Potato Conference in 2021, Yulin, Shaanxi, 24 July 2021, Heilongjiang Science and Technology Press. (In Chinese with English Abstract). 3. Study on hyperspectral remote sensing in agriculture;Tang;Remote Sens. Technol. Appl.,2001 4. Simple reflectance indices track heat and water stress-induced changes in steady-state chlorophyll fluorescence at the canopy scale;Dobrowski;Remote Sens. Environ.,2005 5. Primary and secondary effects of water content on the spectral reflectance of leaves;Carter;Am. J. Bot.,1991
|
|