Abstract
Although Aerial Vehicle images are a viable tool for observing large-scale patterns of fires and their impacts, its application is limited by the complex optical georeferencing procedure due to the lack of distinctive visual features in forest environments. For this reason, an exploratory study on rough and flat terrains was conducted to use and validate the Iterative Ray-Tracing method in combination with a Bearings-Range Extended Kalman Filter as a real-time forest fire georeferencing and filtering algorithm on images captured by an aerial vehicle. The Iterative Ray-Tracing method requires a vehicle equipped with a Global Positioning System (GPS), an Inertial Measurement Unit (IMU), a calibrated camera, and a Digital Elevation Map (DEM). The proposed method receives the real-time input of the GPS, IMU, and the image coordinates of the pixels to georeference (computed by a companion algorithm of fire front detection) and outputs the geographical coordinates corresponding to those pixels. The Unscented Transform B is proposed to characterize the Iterative Ray-Tracing uncertainty. A Bearings-Range filter measurement model is introduced in a sequential filtering architecture to reduce the noise in the measurements, assuming static targets. A performance comparison is done between the Bearings-Only and the Bearings-Range observation models, and between the Extended and Cubature Kalman Filters. In simulation studies with ground truth, without filtering we obtained a georeferencing Root Mean Squared Errors (RMSE) of 30.7 and 43.4 m for the rough and flat terrains respectively, while filtering with the proposed Bearings-Range Extended Kalman Filter showed the best results by reducing the previous RMSE to 11.7 and 19.8 m, respectively. In addition, the comparison of both filter algorithms showed a good performance of Bearings-Range filter which was slightly faster. Indeed, these experiments based on the real data conducted to results demonstrated the applicability of the proposed methodology for the real-time georeferencing forest fires.
Highlights
Forest fires represent one of the biggest catastrophes affecting the land [1]
In this work we propose a georeferencing algorithm for forest environments composed of a EKF with Bearings-Range observation model, where the range is computed via Iterative Ray-Tracing (IRT)
Our best method can be summarized as an Iterative Ray-Tracing, Bearings-Range Extended Kalman Filter, where the measurements are obtained from Global Positioning System (GPS), Inertial Measurement Unit (IMU) and Camera data, supported by a Digital Elevation
Summary
Over 3400 km of land were burned in the European Union [2]. The FIREFRONT project (www.firefront.pt, accessed on 15 September 2021) is an initiative to help combat wildfires using automated image analysis and georeferencing techniques from airborne imagery for real-time decision support. The ability to detect, map and forecast the progression of fires is essential to adequately plan its combat strategy. We describe a study on the techniques to compute the geographical location of the coordinates of observed image pixels corresponding to a fire front. The methods for detecting the fire front pixels in images are outside the scope of the present paper, and have been described in [6,7]
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