Method for collision simulation in virtual hand interaction based on skeletal models
LI Yi1,2, LUO Jian-xun1, CHEN Wei-dong1, ZHENG Xiao-xiang1
1. Qiushi Academy for Advanced Studies, Zhejiang University, Hangzhou 310027, China;2. College of
Information Technology, Zhejiang Chinese Medical University, Hangzhou 310053, China
A simple collision simulation method was proposed based on current methods in order to provide visually and physically realistic feedback of hand movement in hand related neural interface research. The method used a model combined of both solid and deformable objects to keep consistency between physical and visual data in simulation. Experimental results show that the method is valid in providing visually correct results conforming physical rules without penetration. The simulation results are stable and effective for providing visual feedback in such hand related neural interface researches.
LI Yi, LUO Jian-xun, CHEN Wei-dong, ZHENG Xiao-xiang. Method for collision simulation in virtual hand interaction based on skeletal models. J4, 2014, 48(1): 105-112.
[1] PEREZ-MARCOS D, SLATER M, SANCHEZ-VIVES M V. Inducing a virtual hand ownership illusion through a brain-computer interface [J]. NeuroReport, 2009,20(6): 589-594.
[2] SLATER M, PEREZ-MARCOS D, EHRSSON H, et al. Inducing illusory ownership of a virtual body [J]. Frontiers in Neuroscience, 2009, 3(2): 214-220.
[3] ZHUANG J, TRUCCOLO W, VARGAS-IRWIN C, et al. Decoding 3-D reach and grasp kinematics from high-frequency local field potentials in primate primary motor cortex [J]. IEEE Transactions on Biomedical Engineering, 2010, 57(7): 1774-1784.
[4] BARAFF D. Fast contact force computation for non-penetrating rigid bodies [C]∥Proceedings of the 21st Annual Conference on Computer Graphics and Interactive Techniques-SIGGRAPH’94. Orlando: ACM, 1994: 23-34.
[5] WOSLE M, PFEIFFER F. Dynamics of multibody systems containing dependent unilateral constraints with friction [J]. Journal of Vibration and Control, 1996, 2(2): 161-192.
[6] SAUER J, SCHMER E. A constraint-based approach to rigid body dynamics for virtual reality applications [C]∥Proceedings of the ACM Symposium on Virtual reality Software and Technology. Taiwan: ACM, 1998: 153-162.
[7] GUENDELMAN E, BRIDSON R, FEDKIW R. Nonconvex rigid bodies with stacking [C]∥ACM SIGGRAPH 2003 Papers on - SIGGRAPH’03. San Diego: ACM, 2003: 871.
[8] MILLINGTON I. Game physics engine development [M]. San Francisco: Morgan Kaufmann, 2006: 458.
[9] HOWLETT P, HEWITT W T. Mass-spring simulation using adaptive non-active points [J]. Computer Graphics Forum, 1998, 17(3): 345-353.
[10] SELLE A, LENTINE M, FEDKIW R. A mass spring model for hair simulation [J]. ACM Transactions on Graphics, 2008, 27(3):64-73.
[11] GOURRET J P, THALMANN N M, THALMANN D. Simulation of object and human skin formations in a grasping task [J]. ACM SIGGRAPH Computer Graphics, 1989, 23(3): 21-30.
[12] BRO-NIELSEN M, COTIN S. Real-time volumetric deformable models for surgery simulation using finite elements and condensation [J]. Computer Graphics Forum, 1996, 15(3): 57-66.
[13] BRO-NIELSEN M. Finite element modeling in surgery simulation [J]. Proceedings of the IEEE, 1998, 86(3): 490-503.
[14] The bullet engine [EB/OL]. [2012-09-09]. http:∥bulletphysics.org/wordpress/.
[15] BORST C, INDUGULA A P. Realistic virtual grasping [C]∥IEEE Virtual Reality Conference 2005 (VR’05). Bonn: IEEE, 2005: 91-98.
[16] OpenSceneGraph [EB/OL]. [2012-09-09]. http:∥www.openscenegraph.org/projects/osg.
