Title :
A Cellular Neural Network Methodology for Deformable Object Simulation
Author :
Zhong, Yongmin ; Shirinzadeh, Bijan ; Alici, Gursel ; Smith, Julian
Author_Institution :
Robotics & Mechatronics Res. Lab., Monash Univ., Clayton, Vic.
Abstract :
This paper presents a new methodology to simulate soft object deformation by drawing an analogy between a 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 a nonlinear CNN. The novelty of the methodology is that: 1) CNN techniques are established to describe the potential energy distribution of the deformation for extrapolating internal forces and 2) nonlinear materials are modeled with nonlinear CNNs rather than geometric nonlinearity. Integration with a haptic device has been achieved for deformable object simulation with force feedback. The proposed methodology not only predicts the typical behaviors of living tissues, but it also accommodates isotropic, anisotropic, and inhomogeneous materials, as well as local and large-range deformation
Keywords :
biological tissues; cellular neural nets; extrapolation; haptic interfaces; medical computing; cellular neural network methodology; deformable object simulation; elastic deformation; extrapolating internal forces; haptic device; haptic feedback; living tissues; nonlinear materials; potential energy distribution; Anisotropic magnetoresistance; Cellular neural networks; Computational modeling; Deformable models; Finite element methods; Haptic interfaces; Material properties; Potential energy; Solid modeling; Surgery; Analogy systems; cellular neural networks (CNNs); deformation; haptic feedback;
Journal_Title :
Information Technology in Biomedicine, IEEE Transactions on
DOI :
10.1109/TITB.2006.875679
