Abstract
Miniaturized thermal infrared (TIR) cameras that measure surface temperature are increasingly available for use with unmanned aerial vehicles (UAVs). However, deriving accurate temperature data from these cameras is non-trivialsince they are highly sensitive to changes in their internal temperature and low-cost models are often not radiometrically calibrated. We present the results of laboratory and field experiments that tested the extent of the temperature-dependency of a non-radiometric FLIR Vue Pro 640. We found that a simple empirical line calibration using at least three ground calibration points was sufficient to convert camera digital numbers to temperature values for images captured during UAV flight. Although the camera performed well under stable laboratory conditions (accuracy ±0.5 °C), the accuracy declined to ±5 °C under the changing ambient conditions experienced during UAV flight. The poor performance resulted from the non-linear relationship between camera output and sensor temperature, which was affected by wind and temperature-drift during flight. The camera’s automated non-uniformity correction (NUC) could not sufficiently correct for these effects. Prominent vignetting was also visible in images captured under both stable and changing ambient conditions. The inconsistencies in camera output over time and across the sensor will affect camera applications based on relative temperature differences as well as user-generated radiometric calibration. Based on our findings, we present a set of best practices for UAV TIR camera sampling to minimize the impacts of the temperature dependency of these systems.
Highlights
Temperature affects environmental processes at all scales, from the global distribution of plants and animals to the photosynthesis of CO2 molecules in leaf chloroplasts
Thermal cameras mounted on unmanned aerial vehicles (UAVs) can provide high resolution and spatially-resolved surface temperature measurements and, offer a powerful tool for environmental science
The use of Thermal infrared (TIR) cameras on UAVs has been promoted by the availability of miniaturized thermal sensors that are lightweight, low power and fit onto popular UAV platforms
Summary
Temperature affects environmental processes at all scales, from the global distribution of plants and animals to the photosynthesis of CO2 molecules in leaf chloroplasts. Thermal cameras mounted on unmanned aerial vehicles (UAVs) can provide high resolution and spatially-resolved surface temperature measurements and, offer a powerful tool for environmental science. The use of TIR cameras on UAVs has been promoted by the availability of miniaturized thermal sensors that are lightweight, low power and fit onto popular UAV platforms. The cost of these cameras varies from ~€1000 to >€10,000 depending on the resolution of the sensor and the accuracy of the radiometric calibration. Low-cost sensors are generally not radiometrically-calibrated, meaning that they can only provide information on relative temperature differences which are expressed in raw digital numbers (DN, representing the magnitude of the TIR radiance), rather than temperature. It is important to understand what, if any, factors influence their ability to provide data on relative temperature differences
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