Title :
Cellular neural network based deformation simulation with haptic force feedback
Author :
Zhong, Y. ; Shirinzadeh, B. ; Alici, G. ; Smith, J.
Author_Institution :
Robotics & Mechatronics Res. Laboratory, Monash Univ., Clayton, Vic.
Abstract :
This paper presents a new methodology for deformable object modelling by drawing an analogy between cellular neural network (CNN) and elastic deformation. The potential energy stored in an elastic body as a result of a deformation caused by an external force is propagated among mass points by the non-linear CNN activity. An improved CNN model is developed for propagating the energy generated by the external force on the object surface in the natural manner of Poisson equation. The proposed methodology models non-linear materials with nonlinear CNN rather than geometric non-linearity in the most existing deformation methods. It can not only deal with large-range deformations, but it can also accommodate isotropic, anisotropic and inhomogeneous materials by simply modifying constitutive constants
Keywords :
cellular neural nets; elastic deformation; force feedback; haptic interfaces; medical computing; stochastic processes; surgery; virtual reality; Poisson equation; anisotropic materials; cellular neural network; deformable object modelling; deformation simulation; elastic deformation; haptic force feedback; inhomogeneous materials; isotropic materials; nonlinear materials; virtual reality based surgery simulation; Anisotropic magnetoresistance; Cellular neural networks; Computational modeling; Deformable models; Force feedback; Haptic interfaces; Medical simulation; Potential energy; Solid modeling; Surgery;
Conference_Titel :
Advanced Motion Control, 2006. 9th IEEE International Workshop on
Conference_Location :
Istanbul
Print_ISBN :
0-7803-9511-1
DOI :
10.1109/AMC.2006.1631688
