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ISSN 2083-6473
ISSN 2083-6481 (electronic version)
 

 

 

Editor-in-Chief

Associate Editor
Tomasz Neumann
 

Published by
TransNav, Faculty of Navigation
Gdynia Maritime University
3, John Paul II Avenue
81-345 Gdynia, POLAND
www http://www.transnav.eu
e-mail transnav@am.gdynia.pl
Modeling 3D Objects for Navigation Purposes Using Laser Scanning
1 Gdynia Maritime University, Gdynia, Poland
2 University of Warmia and Mazury in Olsztyn, Olsztyn, Poland
3 Studio A+G Interior Design, Interior Photography, Scanning 3d, Land Surveying, Olsztyn, Poland
ABSTRACT: The paper discusses the creation of 3d models and their applications in navigation. It contains a review of available methods and geometric data sources, focusing mostly on terrestrial laser scanning. It presents detailed description, from field survey to numerical elaboration, how to construct accurate model of a typical few storey building as a hypothetical reference in complex building navigation. Hence, the paper presents fields where 3d models are being used and their potential new applications.
REFERENCES
Alkan R. M., Karsidag G., Analysis of the Accuracy of Terrestrial Laser Scanning Measurements, Proceedings of the FIG Working Week, Rome, 2012.
Arun K. S., Huang T. S., Blostein S. D., Least-Squares Fitting of Two 3-D Point Sets, IEEE Transactions on Pattern Analysis and Machine Intelligence, Vol. 9(5), pp. 698–700, 1987.
BHMW, Znaki, skróty, terminologia stosowane na mapach wydawanych przez BHMW, Nr 551, Gdynia, 2012 (in Polish).
Boehler W., Vicent M. B., Marbs A., Investigating Laser Scanner Accuracy, The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol. 34, Part 5/C15, pp. 696-701, 2003.
Ciećko A., Oszczak S., Grzegorzewski M., Ćwiklak J., Wyznaczenie pozycji statku powietrznego oraz dokładności z wykorzystaniem systemu EGNOS w Polsce wschodniej, Logistyka, Nr 6, str. 617-624, 2010 (in Polish).
Clark J., Robson S., Accuracy of Measurements Made with a Cyrax 2500 Laser Scanner Against Surfaces of Known Colour, Survey Review, Vol. 37(294), pp. 626-638, 2004.
Czaplewski K., Podstawy nawigacji morskiej i śródlądowej, Wydawnictwo Bernardinum, Pelplin, 2014 (in Polish).
Ebrahim M. A., 3D Laser Scanners: History, Applications, and Future, Civil Engineering Department, Faculty of Engineering, Assiut University, 2011.
Franceschi M., Teza G., Preto N., Pesci A., Galgaro A., Girardi S., Discrimination Between Marls and Limestones Using Intensity Data from Terrestrial Laser Scanner, ISPRS Journal of Photogrammetry and Remote Sensing, Vol. 64(6), pp. 522-528, 2009.
Gajderowicz I., Odwzorowania kartograficzne. Podstawy, Wydawnictwo Uniwersytetu Warmińsko-Mazurskiego w Olsztynie, 2009 (in Polish).
Hejbudzka K., Lindenbergh R., Soudarissanane S., Humme A., Influence of atmospheric conditions on the range distance and number of returned points in Leica ScanStation 2 point clouds, International Archives of Photogrammetry, Remote Sensing and Spatial Information Science, Vol. XXVIII, Part 5, Commission V Symposium, Newcastle upon Tyne, UK, pp. 282-287, 2010.
Kersten T. P., Sternberg H., Mechelke K., Investigations into the Accuracy Behaviour of the Terrestrial Laser Scanning System Trimble GS100, Optical 3D Measurement Techniques VII, Vol. I, pp. 122-131, 2005.
Kopacz P., Weintrit A., Geodesic Based Trajectories in Navigation Coordinates, The Monthly Magazine on Positioning, Navigation and Beyond, Vol. VII(6), pp. 32-35, 2011.
Lindstaedt M., Graeger T., Mechelke K., Kersten T., Terrestrische Laserscannerim Prüfstand – Geometrische Genauigkeitsuntersuchungenaktuellerterrestrischer Laserscanner, Photogrammetrie, Laserscanning, Optische 3D-Messtechnik, pp. 4-14, 2011 (in German).
Lindstaedt M., Kersten T., Mechelke K., Graeger T., Prüfverfahrenfürterrestrische Laserscanner – Gemeinsamegeometrische Genauigkeitsuntersuchungenverschiedener Laserscanner an der HCU, Photogrammetrie, Laserscanning, Optische 3D-Messtechnik, pp. 264-275, 2012 (in German).
MacEachren A. M., Johnson G. B., The Evolution, Application and Implications of Strip Format Travel Maps, The Cartographic Journal, Vol. 24, pp. 147-158, 1987.
Oszczak B., Tanajewski D., Harmaciński A., Klimczuk M., Modelowanie trójwymiarowe budynków lotniska Dajtki-Olsztyn w aplikacjach AutoCAD Civil 3D i Google SketchUp, Roczniki Geomatyki, Tom IX, Zeszyt 4(48), str. 129-137, 2011 (in Polish).
Resolution of Minister of Administration and Digitalization of 2 November 2015 on Database of Topographic Objects and Base Map, Dz.U. 2015 poz. 2028, 2015.
Rudolf S., 10 Years of Terrestrial Laser Scanning– Technology, Systems and Applications, 2011, https://www.fig.net/news/news_2011/geosiberia_april_2011/Novosibirsk_Geosiberia_2011_Paper_Rudolf_Staiger.pdf. Data dostępu (Accessed 5.12.2015).
Slob S., Hack R., 3D Terrestrial Laser Scanning as a New Field Measurement and Monitoring Technique, Engineering Geology for Infrastructure Planning in Europe, Lecture Notes in Earth Sciences, Springer, Vol. 104, pp. 179-189, 2004.
Specht C., Dąbrowski P., Specht M., Koc W., Chrostowski P., Szmagliński J., Dera M., Skóra M., Mobilne pomiary satelitarne na liniach Pomorskiej Kolei Metropolitalnej, Przegląd Komunikacyjny, Tom 7, str. 9-16, 2016 (in Polish).
Specht C., Deniziuk M., Kamiński M., Wykorzystanie oprogramowania SketchUp jako narzędzia do tworzenia modeli 3D obiektów na potrzeby symulatorów mostka nawigacyjnego, Prace Wydziału Nawigacyjnego Akademii Morskiej w Gdyni, Nr 29, str. 46-54, 2014 (in Polish).
Specht C., Szot T., Specht M., Badanie dokładności personalnych odbiorników GPS w pomiarach dynamicznych, TTS Technika Transportu Szynowego, Nr 10, str. 2547-2555, 2013 (in Polish).
Sternberg H., Kersten T., Comparison of Terrestrial Laser Scanning Systems in Industrial As-Built-Documentation Applications, Optical 3D Measurement Techniques VIII, Vol. I, pp. 389-397, 2007.
U.S. DoD, Global Positioning System Standard Positioning Service Performance Standard, 3rd Edition, 2001.
Vozikis G., Haring A., Vozikis E., Kraus K., Laser Scanning: A New Method for Recording and Documentation in Archaeology, Proceedings of the FIG Working Week, Athens, 2004.
Yilmaz H. M., Yakar M., Yildiz F., Digital Photogrammetry in Obtaining of 3D Model Data of Irregular Small Objects, The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol. 37, Part B3b, pp. 125-130, 2008.
Weintrit A., Development of the IMO e-Navigation Concept – Common Maritime Data Structure. Modern Transport Telematics, Communications in Computer and Information Science, Springer, Vol. 239, pp. 151-163, 2011.
Weintrit A., Morskie pomoce nawigacyjne – definicja, podział i klasyfikacja, Przegląd Telekomunikacyjny + Wiadomości Telekomunikacyjne, Nr 11, str. 1656-1660, 2012 (in Polish).
Citation note:
Specht C., Dąbrowski P., Dumalski A., Hejbudzka K.: Modeling 3D Objects for Navigation Purposes Using Laser Scanning. TransNav, the International Journal on Marine Navigation and Safety of Sea Transportation, Vol. 10, No. 2, doi:10.12716/1001.10.02.12, pp. 301-306, 2016

Other publications of authors:

A. Weintrit, R. Wawruch, C. Specht, L. Gucma, Z. Pietrzykowski

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