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New Drone-Based Index Offers Precision Tool to Detect Wheat Powdery Mildew

By Advos
Researchers have developed a wheat powdery mildew index (WPMI) that integrates UAV hyperspectral imagery and hot-spot analysis to detect, quantify, and track fungal disease across scales, enabling earlier warning and targeted management.
New Drone-Based Index Offers Precision Tool to Detect Wheat Powdery Mildew

A new wheat powdery mildew index (WPMI) provides a practical method to detect, quantify, and track a major fungal disease of winter wheat across multiple spatial scales, according to a study published in the Journal of Remote Sensing on April 10, 2026. By integrating leaf-level spectroscopy, ground canopy measurements, unmanned aerial vehicle (UAV) hyperspectral imagery, and hot-spot analysis, the disease-specific tool can identify infected areas and monitor how wheat powdery mildew spreads or recovers within fields.

Wheat powdery mildew (WPM) is a destructive fungal disease that damages leaf tissues, weakens plant growth, and can cause severe yield losses or even crop failure. Current field diagnosis relies heavily on expert visual inspection, which is labor-intensive, subjective, and difficult to scale. Although hyperspectral remote sensing has shown promise for crop disease detection, many existing vegetation indices were developed for general pigment, biomass, or stress monitoring rather than disease-specific pathogen–host responses. Machine-learning methods also require large, high-quality training datasets. The research team from China Agricultural University, the Beijing Academy of Agriculture and Forestry Sciences, and the Chinese Academy of Agricultural Sciences addressed the need for rapid, field-scale monitoring of WPM in smallholder farms, where disease spread can be spatially uneven and difficult to capture through manual scouting alone.

The study developed two forms of WPMI: WPMIG = (R760 − R554)/(R661 + R554) and WPMIR = (R760 − R661)/(R661 + R554). These indices were designed from disease-sensitive bands in the green, red, and near-infrared regions. Compared with traditional vegetation indices, WPMI more consistently distinguished healthy and infected wheat and better quantified disease index (DI) across leaf, ground canopy, and UAV canopy scales. WPMIG showed particularly strong performance and was selected for UAV-based hot-spot analysis to reveal potential infection and recovery areas.

Researchers collected three years of data from greenhouse and field experiments conducted from 2022 to 2024, including 1,260 leaf spectra and 804 canopy spectra under different infection conditions, wheat varieties, and spatial scales. At the leaf scale, WPMI achieved the highest overall classification accuracy, reaching 85% and 86% for WPMIG and WPMIR, respectively, in the 2022 greenhouse experiment. In field conditions, the two indices achieved 81% and 80% accuracy in 2023, and 80% and 81% in 2024. For disease severity estimation, WPMIG reached R² values of 0.55 to 0.93 at the ground scale and 0.48 to 0.90 at the UAV scale. The UAV-derived WPMIG maps, combined with Getis–Ord Gᵢ* hot-spot analysis, identified clusters of likely infection and tracked spatiotemporal changes across smallholder plots over three growing seasons.

Leaf spectra were collected using a handheld hyperspectral camera, while canopy spectra were acquired using a ground spectrometer and a DJI M600 UAV equipped with a Pika L hyperspectral camera. Linear discriminant analysis was used to select sensitive bands and evaluate classification performance. DI was measured through field surveys following national standards. Linear regression assessed the relationship between WPMI and DI, while hot-spot analysis mapped spatial infection clusters from UAV imagery.

The researchers noted that a disease-specific spectral index can move crop disease monitoring beyond simple image comparison. By linking UAV hyperspectral imagery with spatial hot-spot analysis, the method can help reveal where WPM is emerging, expanding, or declining, offering a potential basis for earlier warning and more targeted disease management. With further validation across regions, wheat varieties, sensors, and disease conditions, WPMI-based UAV monitoring could support precision plant protection and early warning systems for wheat production, helping farmers identify disease hot spots before severe outbreaks occur, reduce unnecessary pesticide use, and improve field-level decision-making. More broadly, this strategy provides a framework for developing disease-specific remote sensing indices for other crop–pathogen systems, contributing to smarter and more resilient agricultural monitoring.

The study is available at DOI: 10.34133/remotesensing.0955.

Advos

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