Comparing Vision-based to Sonar-based 3D Reconstruction

2020 IEEE International Conference on Computational Photography (ICCP) Pub Date : 2020-04-01 DOI:10.1109/ICCP48838.2020.9105273

Netanel Frank, Lior Wolf, D. Olshansky, A. Boonman, Y. Yovel

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引用次数: 3

Abstract

Our understanding of sonar based sensing is very limited in comparison to light based imaging. In this work, we synthesize a ShapeNet variant in which echolocation replaces the role of vision. A new hypernetwork method is presented for 3D reconstruction from a single echolocation view. The success of the method demonstrates the ability to reconstruct a 3D shape from bat-like sonar, and not just obtain the relative position of the bat with respect to obstacles. In addition, it is shown that integrating information from multiple orientations around the same view point helps performance. The sonar-based method we develop is analog to the state-of-the-art single image reconstruction method, which allows us to directly compare the two imaging modalities. Based on this analysis, we learn that while 3D can be reliably reconstructed form sonar, as far as the current technology shows, the accuracy is lower than the one obtained based on vision, that the performance in sonar and in vision are highly correlated, that both modalities favor shapes that are not round, and that while the current vision method is able to better reconstruct the 3D shape, its advantage with respect to estimating the normal's direction is much lower.

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比较基于视觉和基于声纳的3D重建

与基于光的成像相比，我们对基于声纳的传感的理解非常有限。在这项工作中，我们合成了一个ShapeNet变体，其中回声定位取代了视觉的作用。提出了一种基于单一回波定位视图的超网络三维重建方法。该方法的成功证明了利用类似蝙蝠的声纳重建三维形状的能力，而不仅仅是获得蝙蝠相对于障碍物的相对位置。此外，在同一视点周围集成来自多个方向的信息有助于提高性能。我们开发的基于声纳的方法类似于最先进的单图像重建方法，这使我们能够直接比较两种成像方式。基于此分析，我们了解到，虽然可以可靠地从声纳中重建3D，但就目前的技术而言，精度低于基于视觉的3D，声纳和视觉的性能高度相关，两种模式都倾向于非圆形的形状，并且虽然目前的视觉方法能够更好地重建3D形状，但其在估计法线方向方面的优势要低得多。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2020 IEEE International Conference on Computational Photography (ICCP)

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