×

OmniAD: data-driven omni-directional aerodynamics. (English) Zbl 1334.68259


MSC:

68U05 Computer graphics; computational geometry (digital and algorithmic aspects)
68U20 Simulation (MSC2010)
76G99 General aerodynamics and subsonic flows
76M27 Visualization algorithms applied to problems in fluid mechanics
PDFBibTeX XMLCite
Full Text: DOI

References:

[1] Abbott, I. H. 1959.Theory of Wing Sections: Including a Summary of Airfoil Data.Dover Publications.
[2] Andersen, A., Pesavento, U., and Wang, Z. J. 2005. Unsteady aerodynamics of fluttering and tumbling plates.Journal of Fluid Mechanics 541(10), 65–90. · Zbl 1082.76037
[3] Bächer, M., Whiting, E., Bickel, B., and Sorkine-Hornung, O. 2014. Spin-it: Optimizing moment of inertia for spinnable objects.ACM Trans. Graph. (Proc. SIGGRAPH) 33, 4. · Zbl 1396.65032
[4] Batchelor, G. K. 2000.An Introduction to Fluid Dynamics (Cambridge Mathematical Library).Cambridge University Press, 2.
[5] Batty, C., Bertails, F., and Bridson, R. 2007. A fast variational framework for accurate solid-fluid coupling.ACM Trans. Graph. (Proc. SIGGRAPH) 26, 3. · Zbl 1392.74035
[6] Bickel, B., Bächer, M., Otaduy, M. A., Matusik, W., Pfister, H., and Gross, M. 2009. Capture and modeling of non-linear heterogeneous soft tissue.ACM Trans. Graph. (Proc. SIGGRAPH) 28, 3.
[7] Bickel, B., Bächer, M., Otaduy, M. A., Lee, H. R., Pfister, H., Gross, M., and Matusik, W. 2010. Design and fabrication of materials with desired deformation behavior.
[8] Bouguet, J. 2000. Matlab camera calibration toolbox.
[9] Carlson, M., Mucha, P. J., and Turk, G. 2004. Rigid fluid: Animating the interplay between rigid bodies and fluid.ACM Trans. Graph. (Proc. SIGGRAPH) 23, 3, 377–384.
[10] Ceylan, D., Li, W., Mitra, N. J., Agrawala, M., and Pauly, M. 2013. Designing and fabricating mechanical automata from mocap sequences.ACM Trans. Graph. (Proc. SIGGRAPH Asia) 31, 6.
[11] Chen, D., Levin, D. I. W., Didyk, P., Sitthi-Amorn, P., and Matusik, W. 2013. Spec2Fab: A reducer-tuner model for translating specifications to 3D prints.ACM Trans. Graph. (Proc. SIGGRAPH) 32, 4.
[12] Chentanez, N., Goktekin, T. G., Feldman, B. E., and O’Brien, J. F. 2006. Simultaneous coupling of fluids and deformable bodies. InProc. SCA, 83–89.
[13] Cignoni, P., Pietroni, N., Malomo, L., and Scopigno, R. 2014. Field-aligned mesh joinery.ACM Trans. Graph. 33, 1. · Zbl 1288.68221
[14] Coros, S., Thomaszewski, B., Noris, G., Sueda, S., Forberg, M., Sumner, R. W., Matusik, W., and Bickel, B. 2013. Computational design of mechanical characters.ACM Trans. Graph. (Proc. SIGGRAPH) 32, 4. · Zbl 1305.68224
[15] Hildebrand, K., Bickel, B., and Alexa, M. 2012. crdbrd: Shape fabrication by sliding planar slices.Comput. Graphics Forum (Proc. Eurographics) 31, 2pt3, 583–592.
[16] Hullin, M. B., Ihrke, I., Heidrich, W., Weyrich, T., Damberg, G., and Fuchs, M. 2013. Computational fabrication and display of material appearance. InEurographics STARs.
[17] Ihmsen, M., Orthmann, J., Solenthaler, B., Kolb, A., and Teschner, M. 2014. Sph fluids in computer graphics. InEurographics 2014 - State of the Art Reports.
[18] Ju, E., Won, J., Lee, J., Choi, B., Noh, J., and Choi, M. G. 2013. Data-driven control of flapping flight.ACM Trans. Graph. (Proc. SIGGRAPH) 32, 5.
[19] Kazhdan, M., Funkhouser, T., and Rusinkiewicz, S. 2003. Rotation invariant spherical harmonic representation of 3D shape descriptors. InProc. SGP, 156–164.
[20] Klingner, B. M., Feldman, B. E., Chentanez, N., and O’Brien, J. F. 2006. Fluid animation with dynamic meshes.ACM Trans. Graph. (Proc. SIGGRAPH) 25, 3, 820–825.
[21] Lu, L., Sharf, A., Zhao, H., Wei, Y., Fan, Q., Chen, X., Savoye, Y., Tu, C., Cohen-Or, D., and Chen, B. 2014. Build-to-Last: Strength to weight 3D printed objects.ACM Trans. Graph. (Proc. SIGGRAPH) 33, 4. · Zbl 1396.65057
[22] McCrae, J., Singh, K., and Mitra, N. J. 2011. Slices: A shape-proxy based on planar sections.ACM Trans. Graph. (Proc. SIGGRAPH Asia) 30, 6.
[23] Miguel, E., Bradley, D., Thomaszewski, B., Bickel, B., Matusik, W., Otaduy, M. A., and Marschner, S. 2012. Data-driven estimation of cloth simulation models.Comput. Graphics Forum (Proc. Eurographics) 31, 2pt2, 519–528.
[24] Miguel, E., Tamstorf, R., Bradley, D., Schvartzman, S. C., Thomaszewski, B., Bickel, B., Matusik, W., Marschner, S., and Otaduy, M. A. 2013. Modeling and estimation of internal friction in cloth.ACM Trans. Graph. (Proc. SIGGRAPH Asia) 32, 6.
[25] Mori, Y., and Igarashi, T. 2007. Plushie: an interactive design system for plush toys.ACM Trans. Graph. (Proc. SIGGRAPH) 26, 3.
[26] Otaduy, M. A., Bickel, B., Bradley, D., and Wang, H. 2012. Data-driven simulation methods in computer graphics: Cloth, tissue and faces. InACM SIGGRAPH 2012 Courses, SIGGRAPH ’12, 12:1–12:96.
[27] Pai, D. K., Doel, K. V. D., James, D. L., Lang, J., Lloyd, J. E., Richmond, J. L., and Yau, S. H. 2001. Scanning physical interaction behavior of 3D objects. SIGGRAPH ’01, 87–96. · doi:10.1145/383259.383268
[28] Prévost, R., Whiting, E., Lefebvre, S., and Sorkine-Hornung, O. 2013. Make it stand: Balancing shapes for 3D fabrication.ACM Trans. Graph. (Proc. SIGGRAPH) 32, 4. · Zbl 1305.68272
[29] Ramamoorthi, R., and Hanrahan, P. 2002. Frequency space environment map rendering.Proc. of ACM SIGGRAPH ’02 21, 3, 517–526.
[30] Robinson-Mosher, A., Shinar, T., Gretarsson, J., Su, J., and Fedkiw, R. 2008. Two-way coupling of fluids to rigid and deformable solids and shells.ACM Trans. Graph. (Proc. SIGGRAPH) 27, 3.
[31] Saul, G., Lau, M., Mitani, J., and Igarashi, T. 2011. Sketchchair: An all-in-one chair design system for end users. InProc. TEI, ACM, New York, NY, USA, TEI ’11, 73–80.
[32] Schwartzburg, Y., and Pauly, M. 2013. Fabrication-aware design with intersecting planar pieces.Comput. Graphics Forum (Proc. Eurographics) 32, 2pt3, 317–326.
[33] Skouras, M., Thomaszewski, B., Kaufmann, P., Garg, A., Bickel, B., Grinspun, E., and Gross, M. 2014. Designing inflatable structures.ACM Trans. Graph. (Proc. SIGGRAPH) 33, 4. · Zbl 06863168
[34] Song, P., Fu, C.-W., Goswami, P., Zheng, J., Mitra, N. J., and Cohen-Or, D. 2013. Reciprocal frame structures made easy.ACM Trans. Graph. (Proc. SIGGRAPH) 32, 4. · Zbl 1305.68278
[35] Stam, J. 2009. Nucleus: Towards a unified dynamics solver for computer graphics. InIEEE International Conference on Computer-Aided Design and Computer Graphics, IEEE, 1–11.
[36] Stava, O., Vanek, J., Benes, B., Carr, N., and Měch, R. 2012. Stress relief: improving structural strength of 3D printable objects.ACM Trans. Graph. (Proc. SIGGRAPH) 31, 4.
[37] Taira, K., and Colonius, T. 2009. Three-dimensional flows around low-aspect-ratio flat-plate wings at low reynolds numbers.Journal of Fluid Mechanics 623(3), 187–207. · Zbl 1157.76321
[38] Treuille, A., Lewis, A., and Popović, Z. 2006. Model reduction for real-time fluids.ACM Trans. Graph. (Proc. SIGGRAPH) 25, 3.
[39] Umetani, N., Kaufman, D. M., Igarashi, T., and Grinspun, E. 2011. Sensitive couture for interactive garment modeling and editing.ACM Trans. Graph. (Proc. SIGGRAPH) 30, 4.
[40] Umetani, N., Igarashi, T., and Mitra, N. J. 2012. Guided exploration of physically valid shapes for furniture design.ACM Trans. Graph. (Proc. SIGGRAPH) 31, 4.
[41] Umetani, N., Koyama, Y., Schmidt, R., and Igarashi, T. 2014. Pteromys: Interactive design and optimization of free-formed free-flight model airplanes.ACM Trans. Graph. (Proc. SIGGRAPH) 33, 4. · Zbl 06863170
[42] Veen, H. V. 1996.The Tao of Kiteflying: The Dynamics of Tethered Flight, stated first printing ed. Kitelines Bookstore Llc, 3.
[43] Wang, Z. J., Birch, J. M., and Dickinson, M. H. 2004. Unsteady forces and flows in low reynolds number hovering flight: two-dimensional computations vs robotic wing experiments.Journal of Experimental Biology 207, 3, 449–460.
[44] Wang, H., O’Brien, J. F., and Ramamoorthi, R. 2011. Data-driven elastic models for cloth: Modeling and measurement.ACM Trans. Graph. (Proc. SIGGRAPH) 30, 4.
[45] Weissmann, S., and Pinkall, U. 2012. Underwater rigid body dynamics.ACM Trans. Graph. (Proc. SIGGRAPH) 31, 4.
[46] Wejchert, J., and Haumann, D. 1991. Animation aerodynamics.Proc. of ACM SIGGRAPH ’91 25, 4, 19–22.
[47] Welch, G., and Bishop, G. 2001. An introduction to the kalman filter. InSIGGRAPH 2001 Cours, 12–17.
[48] Wright, C. 1998.Kite Flight: Theory and Practice.Diane Pub Co, 4.
[49] Wu, J.-C., and Popović, Z. 2003. Realistic modeling of bird flight animations.ACM Trans. Graph. (Proc. SIGGRAPH) 22, 3.
[50] Xie, H., and Miyata, K. 2013. Stochastic modeling of immersed rigid-body dynamics. InSIGGRAPH Asia 2013 Technical Briefs, 12:1–12:4.
[51] Yuan, Z., Chen, F., and Zhao, Y. 2011. Stochastic modeling of light-weight floating objects. InSymposium on Interactive 3D Graphics and Games, I3D ’11, 213–213. · doi:10.1145/1944745.1944793
[52] Zhong, H., Chen, S., and Lee, C. 2011. Experimental study of freely falling thin disks: Transition from planar zigzag to spiral.Physics of Fluids 23, 1.
[53] Zhu, L., Xu, W., Snyder, J., Liu, Y., Wang, G., and Guo, B. 2012. Motion-guided mechanical toy modeling.ACM Trans. Graph. (Proc. SIGGRAPH Asia) 31, 6.
This reference list is based on information provided by the publisher or from digital mathematics libraries. Its items are heuristically matched to zbMATH identifiers and may contain data conversion errors. In some cases that data have been complemented/enhanced by data from zbMATH Open. This attempts to reflect the references listed in the original paper as accurately as possible without claiming completeness or a perfect matching.