Infra-Red Thermography as a High-Throughput Tool for  Field Phenotyping

Prashar, Ankush; Jones, Hamlyn G.

doi:10.3390/agronomy4030397

Cited by 110 publications

(74 citation statements)

References 112 publications

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“…Thus, a generalization of observed temperatures and model results is strongly limited. On the other hand, such genotype-specific characteristics allow for using thermal imagery as a tool for observing plant response to stress as part of non-invasive phenotyping approaches [96]. Results from our study contribute to the overall understanding of evapotranspiration model behavior for variable cloud cover conditions, when parameterized with remotely sensed surface temperatures.…”

Section: The Impact Of Cloud Cover On Model Resultsmentioning

confidence: 85%

Diurnal Dynamics of Wheat Evapotranspiration Derived from Ground-Based Thermal Imagery

et al. 2014

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Abstract:The latent heat flux, one of the key components of the surface energy balance, can be inferred from remotely sensed thermal infrared data. However, discrepancies between modeled and observed evapotranspiration are large. Thermal cameras might provide a suitable tool for model evaluation under variable atmospheric conditions. Here, we evaluate the results from the Penman-Monteith, surface energy balance and Bowen ratio approaches, which estimate the diurnal course of latent heat fluxes at a ripe winter wheat stand using measured and modeled temperatures. Under overcast conditions, the models perform similarly, and radiometric image temperatures are linearly correlated with the inverted aerodynamic temperature. During clear sky conditions, the temperature of the wheat ear layer could be used to predict daytime turbulent fluxes (root mean squared error and mean absolute error: 20-35 W·m 9776Errors are dependent on the models' ability to simulate diurnal hysteresis effects and are largest during intermittent clouds, due to the discrepancy between the timing of image capture and the time needed for the leaf-air-temperature gradient to adapt to changes in solar radiation. During such periods, we suggest using modeled surface temperatures for temporal upscaling and the validation of image data.

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Section: The Impact Of Cloud Cover On Model Resultsmentioning

confidence: 85%

Diurnal Dynamics of Wheat Evapotranspiration Derived from Ground-Based Thermal Imagery

et al. 2014

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“…It will also look to develop methods using other imaging equipment such as multi-spectral [50][51][52], hyper-spectral [35] and thermal cameras [53,54] to provide information beyond just plant height and growth rate. This should help to open up the opportunity to collect a more complete set of crop phenotype metrics at a spatial and temporal resolution usually unavailable to plant scientists, offering greater insights into varieties behaviours and adaptability under different growing conditions.…”

Section: Resultsmentioning

confidence: 99%

High Throughput Field Phenotyping of Wheat Plant Height and Growth Rate in Field Plot Trials Using UAV Based Remote Sensing

et al. 2016

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Abstract:There is a growing need to increase global crop yields, whilst minimising use of resources such as land, fertilisers and water. Agricultural researchers use ground-based observations to identify, select and develop crops with favourable genotypes and phenotypes; however, the ability to collect rapid, high quality and high volume phenotypic data in open fields is restricting this. This study develops and assesses a method for deriving crop height and growth rate rapidly from multi-temporal, very high spatial resolution (1 cm/pixel), 3D digital surface models of crop field trials produced via Structure from Motion (SfM) photogrammetry using aerial imagery collected through repeated campaigns flying an Unmanned Aerial Vehicle (UAV) with a mounted Red Green Blue (RGB) camera. We compare UAV SfM modelled crop heights to those derived from terrestrial laser scanner (TLS) and to the standard field measurement of crop height conducted using a 2 m rule. The most accurate UAV-derived surface model and the TLS both achieve a Root Mean Squared Error (RMSE) of 0.03 m compared to the existing manual 2 m rule method. The optimised UAV method was then applied to the growing season of a winter wheat field phenotyping experiment containing 25 different varieties grown in 27 m 2 plots and subject to four different nitrogen fertiliser treatments. Accuracy assessments at different stages of crop growth produced consistently low RMSE values (0.07, 0.02 and 0.03 m for May, June and July, respectively), enabling crop growth rate to be derived from differencing of the multi-temporal surface models. We find growth rates range from −13 mm/day to 17 mm/day. Our results clearly display the impact of variable nitrogen fertiliser rates on crop growth. Digital surface models produced provide a novel spatial mapping of crop height variation both at the field scale and also within individual plots. This study proves UAV based SfM has the potential to become a new standard for high-throughput phenotyping of in-field crop heights.

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“…In the last 20 years, advances in DNA sequencing and molecular technologies has significantly improved knowledge of plant genomes; however, current methods to phenotype crops remain slow, expensive, labor-intensive, and often destructive (Furbank and Tester, 2011;Walter et al, 2012;White et al, 2012;Cobb et al, 2013;Dhondt et al, 2013;Fiorani and Schurr, 2013;Araus and Cairns, 2014). Since 2010, rapid high-throughput crop phenotyping methods or 'phenomics' have been discussed as an approach that could significantly improve phenotyping efforts for plant breeding (Furbank and Tester, 2011;Walter et al, 2012;White et al, 2012;Cabrera-Bosquet et al, 2012;Dhondt et al, 2013;Fiorani and Schurr, 2013;Yang et al, 2013;Cobb et al, 2013;Araus and Cairns, 2014;Prashar and Jones, 2014;Deery et al, 2014). These techniques include the application of fluorescence sensing for estimating photosynthesis (Baker, 2008;Munns et al, 2010;Tuberosa, 2012), visible imaging for shoot biomass estimation (Berger et al, 2010;Golzarian et al, 2011), visible-near infrared spectroscopy for identifying physiological changes induced by water and nutrient stresses (Peñuelas et al, 1994;van Maarschalkerweerd et al, 2013), and thermal imaging for detecting water stress (Jones et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

Low-altitude, high-resolution aerial imaging systems for row and field crop phenotyping: A review

Sankaran

Khot

Espinoza

et al. 2015

European Journal of Agronomy

417

293

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Infra-Red Thermography as a High-Throughput Tool for Field Phenotyping

Cited by 110 publications

References 112 publications

Diurnal Dynamics of Wheat Evapotranspiration Derived from Ground-Based Thermal Imagery

Diurnal Dynamics of Wheat Evapotranspiration Derived from Ground-Based Thermal Imagery

High Throughput Field Phenotyping of Wheat Plant Height and Growth Rate in Field Plot Trials Using UAV Based Remote Sensing

Low-altitude, high-resolution aerial imaging systems for row and field crop phenotyping: A review

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