Abstract
In this paper, we address the problem of vision-based satellite recognition and pose estimation, which is to recognize the satellite from multiviews and estimate the relative poses using imaging sensors. We propose a vision-based method to solve these two problems using Gaussian process regression (GPR). Assuming that the regression function mapping from the image (or feature) of the target satellite to its category or pose follows a Gaussian process (GP) properly parameterized by a mean function and a covariance function, the predictive equations can be easily obtained by a maximum-likelihood approach when training data are given. These explicit formulations can not only offer the category or estimated pose by the mean value of the predicted output but also give its uncertainty by the variance which makes the predicted result convincing and applicable in practice. Besides, we also introduce a manifold constraint to the output of the GPR model to improve its performance for satellite pose estimation. Extensive experiments are performed on two simulated image datasets containing satellite images of 1D and 2D pose variations, as well as different noises and lighting conditions. Experimental results validate the effectiveness and robustness of our approach.
Highlights
In this paper, following previous works [12, 19], we address the problem of vision-based satellite recognition and pose estimation, which is to estimate the relative pose of a target satellite and simultaneously recognize its category using imaging sensors
For the 20-class classification problem on BUAA-SID 1.0, we can significantly improve the recognition accuracy when using 12-dimensional Hu’s moment invariants (HU) and 20-dimensional Fourier descriptors (FD), as seen in Tables 1 and 2
Because binary images of space objects can be captured more and completely than high-resolution gray images, shape representations like HU and FD are more suitable for real aerospace applications
Summary
Optical imaging sensors have been widely used as the essential payloads of vision systems in aerospace applications: autonomous rendezvous and docking [1,2,3,4], vision-based landing [5], position and pose estimation [6,7,8,9,10,11,12,13], on-orbit serving [14, 15], space robotics [16], satellite recognition [12, 17,18,19], 3D structure reconstruction and component detection [20, 21], etc. Vision-based recognition and pose estimation of a target satellite are one of the key technologies to achieve these applications. Owing to the improvement of imaging sensors, image data captured by space-based vision systems can be of higher quality. Such high-quality image data contain more detailed information of the target satellite, which could benefit satellite recognition and pose estimation
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