Abstract
Remote sensing and robotics often rely on visual odometry (VO) for localization. Many standard approaches for VO use feature detection. However, these methods will meet challenges if the environments are feature-deprived or highly repetitive. Fourier-Mellin Transform (FMT) is an alternative VO approach that has been shown to show superior performance in these scenarios and is often used in remote sensing. One limitation of FMT is that it requires an environment that is equidistant to the camera, i.e., single-depth. To extend the applications of FMT to multi-depth environments, this paper presents the extended Fourier-Mellin Transform (eFMT), which maintains the advantages of FMT with respect to feature-deprived scenarios. To show the robustness and accuracy of eFMT, we implement an eFMT-based visual odometry framework and test it in toy examples and a large-scale drone dataset. All these experiments are performed on data collected in challenging scenarios, such as, trees, wooden boards and featureless roofs. The results show that eFMT performs better than FMT in the multi-depth settings. Moreover, eFMT also outperforms state-of-the-art VO algorithms, such as ORB-SLAM3, SVO and DSO, in our experiments.
Highlights
Since all the Fourier-Mellin Transform (FMT) implementations only search for one peak in the phase shift diagram (PSD), they will meet difficulties in multi-depth environments, no matter which implementation is used
The scenario only includes two planes with different depths to show the basic effectiveness of extended Fourier-Mellin Transform (eFMT)
EFMT is compared with FMT and the state-of-the-art visual odometry (VO) methods, ORB-SLAM3 [4], SVO [5] and DSO [7], in the real-world environments
Summary
Popular examples of such algorithms are ORB-SLAM [4], SVO [5], LSD-SLAM [6]
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