Detecting Plant Stress Using Thermal and Optical Imagery From an Unoccupied Aerial Vehicle

Bonny Stutsel; Kasper Johansen; Yoann M Malbéteau; Matthew F McCabe

doi:10.3389/fpls.2021.734944

Detecting Plant Stress Using Thermal and Optical Imagery From an Unoccupied Aerial Vehicle

Front Plant Sci. 2021 Oct 27:12:734944. doi: 10.3389/fpls.2021.734944. eCollection 2021.

Authors

Bonny Stutsel¹, Kasper Johansen¹, Yoann M Malbéteau¹, Matthew F McCabe¹

Affiliation

¹ Hydrology, Agriculture and Land Observation, Water Desalination and Reuse Center, King Abdullah University of Science and Technology, Thuwal, Saudi Arabia.

Abstract

Soil and water salinization has global impact on the sustainability of agricultural production, affecting the health and condition of staple crops and reducing potential yields. Identifying or developing salt-tolerant varieties of commercial crops is a potential pathway to enhance food and water security and deliver on the global demand for an increase in food supplies. Our study focuses on a phenotyping experiment that was designed to establish the influence of salinity stress on a diversity panel of the wild tomato species, Solanum pimpinellifolium. Here, we explore how unoccupied aerial vehicles (UAVs) equipped with both an optical and thermal infrared camera can be used to map and monitor plant temperature (T_p) changes in response to applied salinity stress. An object-based image analysis approach was developed to delineate individual tomato plants, while a green-red vegetation index derived from calibrated red, green, and blue (RGB) optical data allowed the discrimination of vegetation from the soil background. T_p was retrieved simultaneously from the co-mounted thermal camera, with T_p deviation from the ambient temperature and its change across time used as a potential indication of stress. Results showed that T_p differences between salt-treated and control plants were detectable across the five separate UAV campaigns undertaken during the field experiment. Using a simple statistical approach, we show that crop water stress index values greater than 0.36 indicated conditions of plant stress. The optimum period to collect UAV-based T_p for identifying plant stress was found between fruit formation and ripening. Preliminary results also indicate that UAV-based T_p may be used to detect plant stress before it is visually apparent, although further research with more frequent image collections and field observations is required. Our findings provide a tool to accelerate field phenotyping to identify salt-resistant germplasm and may allow farmers to alleviate yield losses through early detection of plant stress via management interventions.

Keywords: accessions; phenotyping; plant stress; salt tolerance; thermal infrared; tomato; unmanned aerial vehicle; unoccupied aerial vehicle.