Abstract
Thanks to recent advances at the hardware (e.g., emergence of reliable platforms at low cost) and software (e.g., automated identification of conjugate points in overlapping images) levels, UAV-based 3D reconstruction has been widely used in various applications. However, mitigating the impact of outliers in automatically matched points in UAV imagery, especially when dealing with scenes that has poor and/or repetitive texture, remains to be a challenging task. In spite of the fact that existing literature has already demonstrated that incorporating prior motion information can play an important role in increasing the reliability of the matching process, there is a lack of methodologies that are mainly suited for UAV imagery. Assuming the availability of prior information regarding the trajectory of a UAV-platform, this paper presents a two-point approach for reliable estimation of Relative Orientation Parameters (ROPs) of UAV-based images. This approach is based on the assumption that the UAV platform is moving at a constant flying height while maintaining the camera in a nadir-looking orientation. For this flight scenario, a closed-form solution that can be derived using a minimum of two pairs of conjugate points is established. In order to evaluate the performance of the proposed approach, experimental tests using real stereo-pairs acquired from different UAV platforms have been conducted. The derived results from the comparative performance analysis against the Nistér five-point approach demonstrate that the proposed two-point approach is capable of providing reliable estimate of the ROPs from UAV-based imagery in the presence of poor and/or repetitive texture with high percentage of matching outliers.
Highlights
Automated relative orientation, which defines the position and orientation of one image relative to another one, has been investigated within both the photogrammetric and computer vision research communities (Habib and Kelley, 2001; Heipke, 1997; Zhang et al, 2011)
The errors associated with derived Relative Orientation Parameters (ROPs) from the two adopted approaches while incorporating the automatically-identified conjugate point pairs are shown in Rows 1 and 2 for test, respectively
This paper presents a two-point approach for reliable relative orientation recovery of UAV-based images
Summary
Automated relative orientation, which defines the position and orientation of one image relative to another one, has been investigated within both the photogrammetric and computer vision research communities (Habib and Kelley, 2001; Heipke, 1997; Zhang et al, 2011). Motivated by the concept of the Essential matrix, which encapsulates the epipolar geometry relating stereo-images, an eight-point algorithm was proposed by Longuet-Higgins (1987) for recovering the structure of a scene from two views that have been captured by a calibrated camera. Such eight-point algorithm does not consider the constraints among the nine elements of the Essential matrix (i.e., constraints should be imposed to consider the fact that those elements are defined by five independent parameters). Drawn conclusions and recommendations for future work are introduced
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