# Detection technologies and sensing systems for crop pest identification and infestation severity prediction: a review

**Authors:** Tianhua Chen, Yafei Wang, Jingmin Dang, Fu Zhang, Changji Wang

PMC · DOI: 10.3389/fpls.2026.1765363 · 2026-02-27

## TL;DR

This paper reviews technologies for detecting crop pests using gas sensors, focusing on infrared absorption spectroscopy for improved monitoring in precision agriculture.

## Contribution

The paper provides a comprehensive overview of infrared-based gas sensors for crop pest monitoring, emphasizing their design and application strategies.

## Key findings

- Infrared absorption spectroscopy-based gas sensors offer high sensitivity and scalability for pest detection.
- The paper outlines key technologies and fabrication processes for trace gas sensors in agricultural monitoring.
- Application strategies include transmission network design and platform integration for real-world use.

## Abstract

With the rapid development of precision agriculture technology, agricultural production is gradually shifting from traditional experience-based practices to data-driven decision-making. Pest species identification and scale prediction are crucial technologies in the field of pest detection. Compared with traditional pest monitoring methods, detection based on organic volatile gases released by crops under pest stress provides superior temporal and spatial resolution. The use of gas sensors in crop pest monitoring has great potential for application in future agricultural production. Infrared absorption spectroscopy-based gas sensors have gained widespread attention in crop pest monitoring due to their superior detection sensitivity and extensive scalability. A comprehensive overview of recent advances in intelligent detection methods and equipment for crop pest monitoring is provided. Emphasis is placed on the architecture, operating principles, sensing mechanisms, and fabrication materials of trace gas sensors based on infrared absorption spectroscopy for agricultural pest monitoring. In addition, key technologies involved in their fabrication processes are outlined. Finally, based on the specific characteristics of these sensors, the paper discusses in detail the application strategies of infrared absorption spectroscopy trace gas sensors in crop pest and disease monitoring, including transmission network design, platform integration, and the technical bottlenecks encountered in practical applications. The research will provide scientific foundations and innovative ideas for the development of future crop pest monitoring technologies, addressing the challenges faced by precision agriculture today.

## Figures

8 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12982465/full.md

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Source: https://tomesphere.com/paper/PMC12982465