Jianyong Zhou1, Zu Luo2, Chunquan Li3, Mi Deng4. 1. School of Mechatronic Engineering, Nanchang University, Jiangxi, China. Electronic address: 624235362@QQ.com. 2. School of Information Engineering, Nanchang University, Jiangxi, China. Electronic address: waveluozu@163.com. 3. School of Information Engineering, Nanchang University, Jiangxi, China. Electronic address: lichunquan@ncu.edu.cn. 4. Department of Mathematical Sciences, New Mexico State University, Las Cruces, NM, 88003, USA. Electronic address: dengmi@nmsu.edu.
Abstract
BACKGROUND: When the meshless method is used to establish the mathematical-mechanical model of human soft tissues, it is necessary to define the space occupied by human tissues as the problem domain and the boundary of the domain as the surface of those tissues. Nodes should be distributed in both the problem domain and on the boundaries. Under external force, the displacement of the node is computed by the meshless method to represent the deformation of biological soft tissues. However, computation by the meshless method consumes too much time, which will affect the simulation of real-time deformation of human tissues in virtual surgery. METHODS: In this article, the Marquardt's Algorithm is proposed to fit the nodal displacement at the problem domain's boundary and obtain the relationship between surface deformation and force. When different external forces are applied, the deformation of soft tissues can be quickly obtained based on this relationship. RESULTS AND CONCLUSIONS: The analysis and discussion show that the improved model equations with Marquardt's Algorithm not only can simulate the deformation in real-time but also preserve the authenticity of the deformation model's physical properties.
BACKGROUND: When the meshless method is used to establish the mathematical-mechanical model of human soft tissues, it is necessary to define the space occupied by human tissues as the problem domain and the boundary of the domain as the surface of those tissues. Nodes should be distributed in both the problem domain and on the boundaries. Under external force, the displacement of the node is computed by the meshless method to represent the deformation of biological soft tissues. However, computation by the meshless method consumes too much time, which will affect the simulation of real-time deformation of human tissues in virtual surgery. METHODS: In this article, the Marquardt's Algorithm is proposed to fit the nodal displacement at the problem domain's boundary and obtain the relationship between surface deformation and force. When different external forces are applied, the deformation of soft tissues can be quickly obtained based on this relationship. RESULTS AND CONCLUSIONS: The analysis and discussion show that the improved model equations with Marquardt's Algorithm not only can simulate the deformation in real-time but also preserve the authenticity of the deformation model's physical properties.