The paper is dedicated to the aspects of 3D computational modeling of
Be-103 amphibious aircraft. The paper contains initial Figures and
drawings; the computational modeling is performed in 3 ds Max 3D graphic
modeling system. Models of amphibious aircraft structural components
are produced by polygonal extrusion process. Shading is performed at the
sub-objects level as well as assignment of materials. Figures
illustrating realistic rendering of amphibious aircraft 3D-model are
presented as well.
The main contribution of this article is to create a method of designing
from the initial sketch-es to photorealistic model of amphibious
aircraft. Polygonal modeling method has advantages in the designing of
complex engineering objects. For high-quality rendering of the final
model uses an improved calculating method of lighting.
3D computational modeling, Amphibious aircraft, Projection drawings,
Construction of amphibian aircraft, Polygonal extrusion method, Modeling
of fuselage, Wing, Tail unit, Shading, Rendering.
L. Silveira and N. Santos, "The marina of Horta (Azores islands)–impacts on the local population and in the tourism development," presented at the 7th International Coastal & Marine Tourism Congress, Section 1, 2012.
Z. Marusic, D. Bartulovic, and A. Rukavina, "Hydro aviation model in purpose of improving the tourist transport to Islands," Suvremeni Promet-Modern Traffic, vol. 33, pp. 147-149, 2013. View at Google Scholar
S. S. Sarakinos, I. M. Valakos, and I. K. Nikolos, "A software tool for generic parameterized aircraft design," Advances in Engineering Software, vol. 38, pp. 39–49, 2007. View at Google Scholar | View at Publisher
R. Haimes and M. Drela, "On the construction of aircraft conceptual geometry for high-fidelity analysis and design," presented at the 50th AIAA Aerospace Sciences Meeting Including the New Horizons Fo-rum and Aerospace Exposition 2012, Article number AIAA 2012-0683. USA, 2012.
F. H. Darwish, G. M. Atmeh, and Z. F. Hasan, "Design analysis and modeling of a general aviation aircraft," Jordan Journal of Mechanical and Industrial Engineering, vol. 6, pp. 183-191, 2012. View at Google Scholar
W. A. J. Anemaat, Conceptual airplane design systems. In encyclopaedia of aerospace engineering, R. Blockly, and W. Shyy (Eds). Chichester: John Wiley & Sons, 2010.
The Official Website of the Beriev Aircraft Company, Retrieved from www.beriev.com. [Accessed 18 October 2016], 1996.
The Official Website, Retrieved from http://www.airwar.ru. [Accessed 16 October 2016], 1998.
I. B. Abbasov, Basics of three-dimensional modeling in the graphics system 3 ds Max 2009. Textbook. Moscow: DMK Press, 2009.
V. V. Orekhov and I. B. Abbasov, "Computational modeling of amphibious Be-103," in Proceedings of the Southern Federal University. Technical Sciences, 2011, pp. 121-125.
I. B. Abbasov and V. V. Orekhov, Amphibious computational modeling. – Saarbrucken. Germany: LAP Lambert Academic Publishing, 2012.
I. B. Abbasov and V. V. Orekhov, "Computational modeling of multipurpose amphibious aircraft Be-200," Advances in Engineering Software, vol. 69, pp. 12-17, 2014. View at Google Scholar | View at Publisher
S. M. Yeger, A. M. Matvienko, and I. A. Shatalov, Basics of aircraft: Textbook. M: Mashi-Nostroenie, 2003.
D. P. Raymer, Living in the future; the education and adventures of an advanced aircraft de-signer. Los Angeles: Design Dimension Press, 2009.
This study received no specific financial support.
The authors declare that they have no competing interests.
All authors contributed equally to the conception and design of the study.