2019 |
Agrafiotis, Panagiotis; Skarlatos, Dimitrios; Georgopoulos, Andreas; Karantzalos, Konstantinos In: Remote Sens., vol. 11, no. 19, pp. 2225, 2019, ISSN: 20724292. Abstract | Links | BibTeX | Tags: Aerial imagery, Bathymetry, Data integration, Fusion, LiDAR, Machine Learning, Point Cloud, Refraction effect, Seabed Mapping, SVM, UAV @article{Agrafiotis2019a,The determination of accurate bathymetric information is a key element for near offshore activities; hydrological studies, such as coastal engineering applications, sedimentary processes, hydrographic surveying, archaeological mapping and biological research. Through structure from motion (SfM) and multi-view-stereo (MVS) techniques, aerial imagery can provide a low-cost alternative compared to bathymetric LiDAR (Light Detection and Ranging) surveys, as it offers additional important visual information and higher spatial resolution. Nevertheless, water refraction poses significant challenges on depth determination. Till now, this problem has been addressed through customized image-based refraction correction algorithms or by modifying the collinearity equation. In this article, in order to overcome the water refraction errors in a massive and accurate way, we employ machine learning tools, which are able to learn the systematic underestimation of the estimated depths. In particular, an SVR (support vector regression) model was developed, based on known depth observations from bathymetric LiDAR surveys, which is able to accurately recover bathymetry from point clouds derived from SfM-MVS procedures. Experimental results and validation were based on datasets derived from different test-sites, and demonstrated the high potential of our approach. Moreover, we exploited the fusion of LiDAR and image-based point clouds towards addressing challenges of both modalities in problematic areas. |
2018 |
Menna, Fabio; Agrafiotis, Panagiotis; Georgopoulos, Andreas State of the art and applications in archaeological underwater 3D recording and mapping Miscellaneous 2018, ISSN: 12962074. Abstract | Links | BibTeX | Tags: 3D Recording and Mapping, LiDAR, Photogrammetry, Sonar, Underwater Archaeology @misc{Menna2018,Since remote times, mankind has been bound to water bodies and evidence of human life from the very beginning hides under the water level, off the coasts, under shallow seas or deep oceans, but also inland water bodies of countries all around the world. Recording, documenting and, ultimately, protecting underwater cultural heritage is an obligation of mankind and dictated by international treaties like the Convention on the Protection of the Underwater Cultural Heritage that fosters and encourages the use of “non-destructive techniques and survey methods in preference over the recovery of objects”. 3D digital surveying and mapping techniques represent an invaluable set of effective tools for reconnaissance, documentation, monitoring, but also public diffusion and awareness of underwater cultural heritage (UCH) assets. This paper presents an extensive review over the sensors and the methodologies used in archaeological underwater 3D recording and mapping together with relevant highlights of well renowned projects in 3D recording underwater. |
2019 |
In: Remote Sens., vol. 11, no. 19, pp. 2225, 2019, ISSN: 20724292. |
2018 |
State of the art and applications in archaeological underwater 3D recording and mapping Miscellaneous 2018, ISSN: 12962074. |