“Real-time Wing Deformation Simulations for Flying Insects”
Conference:
Type(s):
Title:
- Real-time Wing Deformation Simulations for Flying Insects
Presenter(s)/Author(s):
Abstract:
This paper presents an efficient skeleton-driven model specifically designed to real-time simulate realistic wing deformations across a wide range of flying insects. Various simulation experiments, comparisons, and user studies demonstrated the effectiveness, robustness, and adaptability of the proposed model.
References:
[1]
Daniel D Aguayo, Fernando Mendoza Santoyo, H Manuel, Manuel D Salas-Araiza, Cristian Caloca-Mendez, and David Asael Gutierrez Hernandez. 2010. Insect wing deformation measurements using high speed digital holographic interferometry. Optics express 18, 6 (2010), 5661?5667.
[2]
Yi Bai, Jia-Jia Dong, De-Long Guan, Juan-Ying Xie, and Sheng-Quan Xu. 2016. Geographic variation in wing size and shape of the grasshopper Trilophidia annulata (Orthoptera: Oedipodidae): morphological trait variations follow an ecogeographical rule. Scientific reports 6, 1 (2016), 1?15.
[3]
David Baraff and Andrew Witkin. 1998. Large steps in cloth simulation. In Proceedings of the 25th annual conference on Computer graphics and interactive techniques. 43?54.
[4]
Jernej Barbi? and Doug L James. 2005. Real-time subspace integration for St. Venant-Kirchhoff deformable models. ACM transactions on graphics (TOG) 24, 3 (2005), 982?990.
[5]
Mikl?s Bergou, Max Wardetzky, Stephen Robinson, Basile Audoly, and Eitan Grinspun. 2008. Discrete elastic rods. In ACM SIGGRAPH 2008 papers. 1?12.
[6]
James F Blinn. 1978. Simulation of wrinkled surfaces. ACM SIGGRAPH computer graphics 12, 3 (1978), 286?292.
[7]
Robert Bridson, Sebastian Marino, and Ronald Fedkiw. 2005. Simulation of clothing with folds and wrinkles. In ACM SIGGRAPH 2005 Courses. 3?es.
[8]
Hsiao-Yu Chen, Arnav Sastry, Wim M van Rees, and Etienne Vouga. 2018. Physical simulation of environmentally induced thin shell deformation. ACM Transactions on Graphics (TOG) 37, 4 (2018), 1?13.
[9]
Qiang Chen, Tingsong Lu, Yang Tong, Yuming Fang, and Zhigang Deng. 2022a. A Practical Method for Butterfly Motion Capture. In Proceedings of the 15th ACM SIGGRAPH Conference on Motion, Interaction and Games (Guanajuato, Mexico) (MIG ?22). Association for Computing Machinery, New York, NY, USA, Article 8, 9 pages.
[10]
Qiang Chen, Tingsong Lu, Yang Tong, Guoliang Luo, Xiaogang Jin, and Zhigang Deng. 2022b. A Practical Model for Realistic Butterfly Flight Simulation. ACM Transactions on Graphics (TOG) 41, 3 (2022), 1?12.
[11]
Peng Cheng, Jinsong Hu, Guofeng Zhang, Lei Hou, Boqin Xu, and Xiaoping Wu. 2008. Deformation measurements of dragonfly?s wings in free flight by using Windowed Fourier Transform. Optics and lasers in engineering 46, 2 (2008), 157?161.
[12]
Min Gyu Choi, Seung Yong Woo, and Hyeong-Seok Ko. 2007. Real-time simulation of thin shells. In Computer Graphics Forum, Vol. 26. Wiley Online Library, 349?354.
[13]
John Davenport. 1994. How and why do flying fish fly?Reviews in Fish Biology and Fisheries 4, 2 (1994), 184?214.
[14]
Michael H Dickinson, Claire T Farley, Robert J Full, MAR Koehl, Rodger Kram, and Steven Lehman. 2000. How animals move: an integrative view. science 288, 5463 (2000), 100?106.
[15]
Michael H Dickinson, Fritz-Olaf Lehmann, and Sanjay P Sane. 1999. Wing rotation and the aerodynamic basis of insect flight. Science 284, 5422 (1999), 1954?1960.
[16]
William Dickson, Andrew Straw, Christian Poelma, and Michael Dickinson. 2006. An integrative model of insect flight control. In 44th AIAA Aerospace Sciences Meeting and Exhibit. 34.
[17]
DA Dorsett. 1962. Preparation for flight by hawk-moths. Journal of Experimental Biology 39, 4 (1962), 579?588.
[18]
Robert Dudley. 2002. The biomechanics of insect flight: form, function, evolution. Princeton University Press.
[19]
Charles Porter Ellington. 1984. The aerodynamics of hovering insect flight. I. The quasi-steady analysis. Philosophical Transactions of the Royal Society of London. B, Biological Sciences 305, 1122 (1984), 1?15.
[20]
J?r?me H?pffner and Yoshitsugu Naka. 2011. Oblique waves lift the flapping flag. Physical Review Letters 107, 19 (2011), 194502.
[21]
LC Johansson and P Henningsson. 2021. Butterflies fly using efficient propulsive clap mechanism owing to flexible wings. Journal of the Royal Society Interface 18, 174 (2021), 20200854.
[22]
Eunjung Ju, Jungdam Won, Jehee Lee, Byungkuk Choi, Junyong Noh, and Min Gyu Choi. 2013. Data-driven control of flapping flight. ACM Transactions on Graphics (TOG) 32, 5 (2013), 1?12.
[23]
Chang-kwon Kang, Jacob Cranford, Madhu K. Sridhar, Deepa Kodali, David Brian Landrum, and Nathan Slegers. 2018. Experimental Characterization of a Butterfly in Climbing Flight. AIAA Journal 56, 1 (2018), 15?24.
[24]
Ladislav Kavan, Steven Collins, Ji?? ??ra, and Carol O?Sullivan. 2007. Skinning with dual quaternions. In Proceedings of the 2007 symposium on Interactive 3D graphics and games. 39?46.
[25]
Ladislav Kavan, Dan Gerszewski, Adam W Bargteil, and Peter-Pike Sloan. 2011. Physics-inspired upsampling for cloth simulation in games. In ACM SIGGRAPH 2011 papers. 1?10.
[26]
Christopher Koehler, Zongxian Liang, Zachary Gaston, Hui Wan, and Haibo Dong. 2012. 3D reconstruction and analysis of wing deformation in free-flying dragonflies. Journal of Experimental Biology 215, 17 (2012), 3018?3027.
[27]
Christopher Koehler, Thomas Wischgoll, Haibo Dong, and Zachary Gaston. 2011. Vortex visualization in ultra low Reynolds number insect flight. IEEE transactions on visualization and computer graphics 17, 12 (2011), 2071?2079.
[28]
Thomas Lecuit and Lo?c Le Goff. 2007. Orchestrating size and shape during morphogenesis. Nature 450, 7167 (2007), 189?192.
[29]
Patrick Ledda, Alan Chalmers, Tom Troscianko, and Helge Seetzen. 2005. Evaluation of tone mapping operators using a high dynamic range display. ACM Transactions on Graphics (TOG) 24, 3 (2005), 640?648.
[30]
Fritz-Olaf Lehmann, Stanislav Gorb, Nazri Nasir, and Peter Sch?tzner. 2011. Elastic deformation and energy loss of flapping fly wings. Journal of Experimental Biology 214, 17 (2011), 2949?2961.
[31]
Weizi Li, David Wolinski, Julien Pettr?, and Ming C. Lin. 2015. Biologically-inspired visual simulation of insect swarms. In Computer Graphics Forum, Vol. 34. Wiley Online Library, 425?434.
[32]
Yifei Li, Tao Du, Kui Wu, Jie Xu, and Wojciech Matusik. 2022. DiffCloth: Differentiable cloth simulation with dry frictional contact. ACM Transactions on Graphics (TOG) 42, 1 (2022), 1?20.
[33]
Xiaohan Ma and Zhigang Deng. 2009. Natural eye motion synthesis by modeling gaze-head coupling. In 2009 IEEE Virtual Reality Conference. IEEE, 143?150.
[34]
Hisayoshi Naka and Hiromu Hashimoto. 2015. Effects of deformation and vibration characteristics of wings on flapping flight. Mechanical Engineering Journal 2, 1 (2015), 14?00262.
[35]
Hamed Rajabi, Sepehr H Eraghi, Ali Khaheshi, Arman Toofani, Cherryl Hunt, and Robin J Wootton. 2022. An insect-inspired asymmetric hinge in a double-layer membrane. Proceedings of the National Academy of Sciences 119, 45 (2022), e2211861119.
[36]
H Rajabi and SN Gorb. 2020. How do dragonfly wings work? A brief guide to functional roles of wing structural components. International journal of odonatology 23, 1 (2020), 23?30.
[37]
Hamed Rajabi, M Rezasefat, A Darvizeh, J-H Dirks, SH Eshghi, A Shafiei, T Mirzababaie Mostofi, and Stas N Gorb. 2016. A comparative study of the effects of constructional elements on the mechanical behaviour of dragonfly wings. Applied Physics A 122 (2016), 1?13.
[38]
Mary K Salcedo, Jordan Hoffmann, Seth Donoughe, and L Mahadevan. 2019. Computational analysis of size, shape and structure of insect wings. Biology Open 8, 10 (2019), bio040774.
[39]
Andrew Selle, Michael Lentine, and Ronald Fedkiw. 2008. A mass spring model for hair simulation. In ACM SIGGRAPH 2008 papers. 1?11.
[40]
Jonas Spillmann and Matthias Teschner. 2007. CoRdE: Cosserat rod elements for the dynamic simulation of one-dimensional elastic objects. In Proceedings of the 2007 ACM SIGGRAPH/Eurographics symposium on Computer animation. 63?72.
[41]
Tien Van Truong, Quoc-Viet Nguyen, and Heow Pueh Lee. 2017. Bio-inspired flexible flapping wings with elastic deformation. Aerospace 4, 3 (2017), 37.
[42]
Xinjie Wang, Xiaogang Jin, Zhigang Deng, and Linling Zhou. 2014. Inherent noise-aware insect swarm simulation. In Computer Graphics Forum, Vol. 33. Wiley Online Library, 51?62.
[43]
Henja-Niniane Wehmann, Lars Heepe, Stanislav N Gorb, Thomas Engels, and Fritz-Olaf Lehmann. 2019. Local deformation and stiffness distribution in fly wings. Biology open 8, 1 (2019), bio038299.
[44]
Tyler Wilson and Roberto Albertani. 2014. Wing-flapping and abdomen actuation optimization for hovering in the butterfly Idea leuconoe. In 52nd Aerospace Sciences Meeting. 0009.
[45]
Jungdam Won, Jongho Park, Kwanyu Kim, and Jehee Lee. 2017. How to train your dragon: example-guided control of flapping flight. ACM Transactions on Graphics (TOG) 36, 6 (2017), 1?13.
[46]
Jungdam Won, Jungnam Park, and Jehee Lee. 2018. Aerobatics control of flying creatures via self-regulated learning. ACM Transactions on Graphics (TOG) 37, 6 (2018), 1?10.
[47]
Robin J Wootton. 1981. Support and deformability in insect wings. Journal of Zoology 193, 4 (1981), 447?468.
[48]
Botao Wu, Zhendong Wang, and Huamin Wang. 2022. A GPU-Based Multilevel Additive Schwarz Preconditioner for Cloth and Deformable Body Simulation. ACM Trans. Graph. 41, 4, Article 63 (jul 2022), 14 pages.
[49]
Jia-chi Wu and Zoran Popovi?. 2003. Realistic modeling of bird flight animations. ACM Transactions on Graphics (TOG) 22, 3 (2003), 888?895.
[50]
Pin Wu, Peter Ifju, and Bret Stanford. 2010. Flapping wing structural deformation and thrust correlation study with flexible membrane wings. AIAA journal 48, 9 (2010), 2111?2122.
[51]
Wei Xiang, Xinran Yao, He Wang, and Xiaogang Jin. 2020. FASTSWARM: A data-driven framework for real-time flying insect swarm simulation. Computer Animation and Virtual Worlds 31, 4-5 (2020), e1957.
[52]
John Young, Simon M Walker, Richard J Bomphrey, Graham K Taylor, and Adrian LR Thomas. 2009. Details of insect wing design and deformation enhance aerodynamic function and flight efficiency. Science 325, 5947 (2009), 1549?1552.
[53]
Lingxiao Zheng, Tyson L Hedrick, and Rajat Mittal. 2013. Time-varying wing-twist improves aerodynamic efficiency of forward flight in butterflies. PloS one 8, 1 (2013), e53060.
