Abstract
Abstract. The digital surface models (DSM) fusion algorithms are one of the ongoing challenging problems to enhance the quality of 3D models, especially for complex regions with variable radiometric and geometric distortions like satellite datasets. DSM generation using Multiview stereo analysis (MVS) is the most common cost-efficient approach to recover elevations. Algorithms like Census-semi global matching (SGM) and Convolutional Neural Networks (MC-CNN) have been successfully implemented to generate the disparity and recover DSMs; however, their performances are limited when matching stereo pair images with ill-posed regions, low texture, dense texture, occluded, or noisy, which can yield missing or incorrect elevation values, in additions to fuzzy boundaries. DSM fusion algorithms have proven to tackle such problems, but their performance may vary based on the quality of the input and the type of fusion which can be classified into adaptive and non-adaptive. In this paper, we evaluate the performance of the adaptive and nonadaptive fusion methods using median filter, adaptive median filter, K-median clustering fusion, weighted average fusion, and adaptive spatiotemporal fusion for DSM generated using Census and MC-CNN. We perform our evaluation on 9 testing regions using stereo pair images from Worldview-3 satellite to generate DSMs using Census and MC-CNN. Our results show that adaptive fusion algorithms are more accurate than non-adaptive algorithms in predicting elevations due to their ability to learn from temporal and contextual information. Our results also show that MC-CNN produces better fusion results with a lower overall average RMSE than Census.
Highlights
The quality of the digital surface model (DSM) generated from satellite images has always been a crucial element to most remote sensing and photogrammetry applications
Fusion is the process of combining multi-temporal digital surface models (DSM) into a single highquality DSM; it takes advantage of the redundant temporal information to compensate for the incorrect representations or missing elevation points (Albanwan and Qin, 2020; Cigla et al, 2017; Papasaika et al, 2008)
Other studies have shown that the uncertainty of the DSM can be correlated with the class cover type (Albanwan and Qin, 2020), for instance, trees and grass changes based on the acquisition date and season, which can adversely influence the performance of Multiview stereo analysis (MVS) algorithm, and reduces the DMS uncertainty, whereas structures like buildings and roads are less changeable over time and most of the times have lower uncertainty
Summary
The quality of the digital surface model (DSM) generated from satellite images has always been a crucial element to most remote sensing and photogrammetry applications. Other studies have shown that the uncertainty of the DSM can be correlated with the class cover type (Albanwan and Qin, 2020), for instance, trees and grass changes based on the acquisition date and season, which can adversely influence the performance of MVS algorithm, and reduces the DMS uncertainty, whereas structures like buildings and roads are less changeable over time and most of the times have lower uncertainty.
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