Abstract
In unstable atmospheric conditions, using on-board irradiance sensors is one of the only robust methods to convert unmanned aerial vehicle (UAV)-based optical remote sensing data to reflectance factors. Normally, such sensors experience significant errors due to tilting of the UAV, if not installed on a stabilizing gimbal. Unfortunately, such gimbals of sufficient accuracy are heavy, cumbersome, and cannot be installed on all UAV platforms. In this paper, we present the FGI Aerial Image Reference System (FGI AIRS) developed at the Finnish Geospatial Research Institute (FGI) and a novel method for optical and mathematical tilt correction of the irradiance measurements. The FGI AIRS is a sensor unit for UAVs that provides the irradiance spectrum, Real Time Kinematic (RTK)/Post Processed Kinematic (PPK) GNSS position, and orientation for the attached cameras. The FGI AIRS processes the reference data in real time for each acquired image and can send it to an on-board or on-cloud processing unit. The novel correction method is based on three RGB photodiodes that are tilted 10° in opposite directions. These photodiodes sample the irradiance readings at different sensor tilts, from which reading of a virtual horizontal irradiance sensor is calculated. The FGI AIRS was tested, and the method was shown to allow on-board measurement of irradiance at an accuracy better than ±0.8% at UAV tilts up to 10° and ±1.2% at tilts up to 15°. In addition, the accuracy of FGI AIRS to produce reflectance-factor-calibrated aerial images was compared against the traditional methods. In the unstable weather conditions of the experiment, both the FGI AIRS and the on-ground spectrometer were able to produce radiometrically accurate and visually pleasing orthomosaics, while the reflectance reference panels and the on-board irradiance sensor without stabilization or tilt correction both failed to do so. The authors recommend the implementation of the proposed tilt correction method in all future UAV irradiance sensors if they are not to be installed on a gimbal.
Highlights
Unmanned Aerial Vehicle (UAV)-borne imaging and orthorectification are currently trivial tasks, allowing almost anyone to acquire visually stunning aerial imagery
We present the FGI Aerial Image Reference System (FGI AIRS) developed at the Finnish Geospatial Research Institute (FGI) and a novel method for optical and mathematical tilt correction of the irradiance measurements
The authors recommend the implementation of the proposed tilt correction method in all future unmanned aerial vehicle (UAV) irradiance sensors if they are not to be installed on a gimbal
Summary
Unmanned Aerial Vehicle (UAV)-borne imaging and orthorectification are currently trivial tasks, allowing almost anyone to acquire visually stunning aerial imagery. Numerous commercial companies offer multi- and hyperspectral sensors to be used with drones. This seemingly makes acquisition of advanced radiometric data trivial, but solutions for the proper calibration and processing of the data are not standardized [1] and not as readily available as the hardware. The radiance images need to be converted to reflectance factors and made invariant of the intensity of illumination i.e., irradiance. The reflectance factor conversion is done by normalizing the pixel radiance values (L) by irradiance of illumination (E) that was present at the target during the image exposure
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