A Neural Process Approach for Probabilistic Reconstruction of No-Data Gaps in Lunar Digital Elevation Maps
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With the advent of NASA's lunar reconnaissance orbiter (LRO), a large amount of high-resolution digital elevation maps (DEMs) have been constructed by using narrow-angle cameras (NACs) to characterize the Moon's surface. However, NAC DEMs commonly contain no-data gaps (voids), which makes the map less reliable. To resolve the issue, this paper provides a deep-learning-based framework for the probabilistic reconstruction of no-data gaps in NAC DEMs. The framework is built upon a state of the art stochastic process model, attentive neural processes (ANP), and predicts the conditional distribution of elevation on the target coordinates (latitude and longitude) conditioned on the observed elevation data in nearby regions. Furthermore, this paper proposes sparse attentive neural processes (SANPs) that not only reduces the linear computational complexity of the ANP O(N) to the constant complexity O(K) but enhance the reconstruction performance by preventing overfitting and over-smoothing problems. The proposed method is evaluated on the Apollo 17 landing site (20.0N and 30.4E), demonstrating that the suggested approach successfully reconstructs no-data gaps with uncertainty analysis while preserving the high resolution of original NAC DEMs.
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