Browse > Article
http://dx.doi.org/10.7315/CDE.2017.202

Augmented Visualization of Modeling & Simulation Analysis Results  

Kim, Minseok (Dept. of Industrial Engineering, Chonnam Nat'l Univ.)
Seo, Dong Woo (KISTI)
Lee, Jae Yeol (Dept. of Industrial Engineering, Chonnam Nat'l Univ.)
Kim, Jae Sung (KISTI)
Publication Information
Korean Journal of Computational Design and Engineering / v.22, no.2, 2017 , pp. 202-214 More about this Journal
Abstract
The augmented visualization of analysis results can play an import role as a post-processing tool for the modeling & simulation (M&S) technology. In particular, it is essential to develop such an M&S tool which can run on various multi-devices. This paper presents an augmented reality (AR) approach to visualizing and interacting with M&S post-processing results through mobile devices. The proposed approach imports M&S data, extracts analysis information, and converts the extracted information into the one used for AR-based visualization. Finally, the result can be displayed on the mobile device through an AR marker tracking and a shader-based realistic rendering. In particular, the proposed method can superimpose AR-based realistic scenes onto physical objects such as 3D printing-based physical prototypes in a seamless manner, which can provide more immersive visualization and natural interaction of M&S results than conventional VR or AR-based approaches. A user study has been performed to analyze the qualitative usability. Implementation results will also be given to show the advantage and effectiveness of the proposed approach.
Keywords
Augmented reality; Augmented visualization & interaction; Modeling & simulation; Rapid prototype;
Citations & Related Records
Times Cited By KSCI : 2  (Citation Analysis)
연도 인용수 순위
1 Suri, R. and Hidebrant, R., 1997, Modeling Flexible Manufacturing System, Journal of Manufacturing Systems, 3(1), pp.27-38.
2 Kim, J.H., Lee, C.S. and Kim, S.J., 2005, High-Performance Domainwise Parallel Direct Solver for Large-Scale Structural Analysis, AIAA Journal, 43(30), pp.662-670.   DOI
3 Kim, J.H. and Woo, S.W., 2005, Study on High-Performance Computing Technique for Largescale Structural Analysis, Journal of the Computational Structural Engineering Institute of Korea, 18(1), pp.37-44.
4 Kim, J.S., Lee, S.M., Lee, J.Y., Jeong, H.S. and Lee, S.M., 2012, Development of Pre- and Post-processing System for Supercomputing based Large-scale Structural Analysis, Transactions of the Society of CAD/CAM Engineers, 17(2), pp.123-131.   DOI
5 Seo, D.W., Lee, J.Y, Lee, S.M., Kim, J.S. and Park, H.W., 2013, Multi-View Supporting VR/AR Visualization System for Supercomputing-based Engineering Analysis Services, Korean Journal of Computational Design and Engineering, 18(6), pp.428-438.   DOI
6 Bhardwaj, M., Pierson, K., Reese, G., Walsh, T., Day, D., Alvin, K., Peery, J., Farhat, C. and Lesoinne, M, 2002, Salinas: A Scalable Software for High-Performance Structural and Solid Mechanics Simulations, Proc. Supercomputing Conf., Baltimore, pp.16-22.
7 Nee, A.Y.C., Ong, S.K., Chryssolouris, G. and Mourtzis, D., 2012, Augmented Reality Applications in Design and Manufacturing, CIRP Annals-Manufacturing Technology, 61(2), pp.657-679.   DOI
8 Doil, F., Schreiber, W., Alt, T. and Patron, C., 2003, Augmented Reality for Manufacturing Planning, Proc. Workshop on Virtual Environments, pp.71-76.
9 Huang, J.M., Ong, S.K. and Nee, A.Y.C., 2015, Real-time Finite Element Structural Analysis in Augmented Reality, Advances in Engineering Software, 87, pp.43-56.   DOI
10 Uva, A.E., Cristiano, S., Fiorentino, M. and Monno, G., 2010, Distributed Design Review Using Tangible Augmented Technical Drawings, Computer-Aided Design, 42(5), pp.364-372.   DOI
11 Bruno, F., Caruso, F., De Napoli, L. and Muzzupappa, M., 2006, Visualization of Industrial Engineering Data in Augmented Reality, Journal of Visualization, 9(3), pp.319-329.   DOI
12 Heuveline, V., Ritterbusch, S. and Ronnas, S., 2011, Augmented Reality for Urban Simulation Visualization, Proc. 1st International Conf. on Advanced Communications and Computation, pp.115-119.
13 Weidlich, D., Scherer, S. and Wabner, M., 2008, Analyses Using VR/AR Visualization, IEEE Computer Graphics and Applications, 28(5), pp.84-86.   DOI
14 Heun, V., Kasahara, S. and Maes, P., 2013, Smarter Obects: Using AR Technology to Program Physical Objects and Their Interactions, Proc. CHI'13 Extended Abstract, pp.961-966.
15 Calculix, www.calculix.de/
16 Lee, J.Y., Rhee, G.W. and Park, H., 2009, AR/RP-based Tangible Interactions for Collaborative Design Evaluation of Digital Products, International Journal of Advanced Manufacturing Technology, 45(7-8), pp.649-665.   DOI
17 Park, H., Moon, H.C. and Lee, J.Y., 2009, Tangible Augmented Prototyping of Digital Handheld Products, Computers in Industry, 60(2), pp.114-125.   DOI
18 Park, H. and Moon, H.C., 2013, Design Evaluation of Information Appliances Using Augmented Reality-based Tangible Interaction, Computers in Industry, 64(7), pp.854-868.   DOI
19 Park, H. and Moon, H.C., 2011, AR-based Tangible Interaction Using a Finger Fixture for Digital Handheld Products, Korean Journal of Computational Design and Engineering, 16(1), pp.1-10.
20 Opencascade, https://www.opencascade.com/
21 OpenFoam, http://www.openfoam.com/
22 Unity3d, http://unity3d.com
23 Vuforia, https://develper.vuforia.com
24 Epson Moverio BT-200, https://epson.com/moverio-augmented-reality-smart-glasses
25 Microsoft HoloLens, https://www.microsoft.com/microsoft-hololens/en-us