Abstract
Local image features are invariant to in-plane rotations and robust to minor viewpoint changes. However, the current detectors and descriptors for local image features fail to accommodate out-of-plane rotations larger than 25°–30°. Invariance to such viewpoint changes is essential for numerous applications, including wide baseline matching, 6D pose estimation, and object reconstruction. In this study, we present a general embedding that wraps a detector/descriptor pair in order to increase viewpoint invariance by exploiting input depth maps. The proposed embedding locates smooth surfaces within the input RGB-D images and projects them into a viewpoint invariant representation, enabling the detection and description of more viewpoint invariant features. Our embedding can be utilized with different combinations of descriptor/detector pairs, according to the desired application. Using synthetic and real-world objects, we evaluated the viewpoint invariance of various detectors and descriptors, for both standalone and embedded approaches. While standalone local image features fail to accommodate average viewpoint changes beyond 33.3°, our proposed embedding boosted the viewpoint invariance to different levels, depending on the scene geometry. Objects with distinct surface discontinuities were on average invariant up to 52.8°, and the overall average for all evaluated datasets was 45.4°. Similarly, out of a total of 140 combinations involving 20 local image features and various objects with distinct surface discontinuities, only a single standalone local image feature exceeded the goal of 60° viewpoint difference in just two combinations, as compared with 19 different local image features succeeding in 73 combinations when wrapped in the proposed embedding. Furthermore, the proposed approach operates robustly in the presence of input depth noise, even that of low-cost commodity depth sensors, and well beyond.
Highlights
Local image features are major low-level building blocks in various computer vision and image processing algorithms; they have a certain degree of sensitivity to viewpoint changes
Local image features suffer from a lack of robustness to viewpoint changes
Improving the viewpoint invariance has compelling applications in different fields and is gaining increasing attention, especially with the availability of geometric information attained through depth sensors
Summary
Local image features are major low-level building blocks in various computer vision and image processing algorithms; they have a certain degree of sensitivity to viewpoint changes. Despite the current trend of using machine learning for low-level local image features [5,6,7,8,9,10,11], or even for high-level tasks, such as 6D pose estimation, [12,13,14,15,16], several hand-crafted features are still actively employed in various algorithms. Transform) [19], and SURF (Speeded Up Robust Features) [20] These are local intensity-image approaches, which typically detect keypoints and describe their features from image patches ( the name local) with gray or trichromatic intensities under some geometric assumptions. Achieving viewpoint invariance will improve the efficiency and robustness of various computer vision ill-posed problems, including wide baseline matching, 6D pose estimation (i.e., rigid body transformation), 3D reconstruction, recognition by reconstruction, and visual SLAM
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