Abstract. Using methods from the computational sciences to improve the quality of health care is an important part of current medical progress. A particulary complex field is surgery simulation, where the fidelity of the systems is still unsatisfactory. We present a finite element system based on a sophisticated material law, better suited for dynamical computations than the standard approaches. To balance computational cost, a hierarchical basis is employed, allowing detail where needed. For time integration the use of a stabilized Runge-Kutta method is proposed.
This paper presents a numerical method for interactive (real-time) simulations, which considerably i...
Abstract. We present our systematic efforts in advancing the computational performance of physically...
The use of biomechanical modelling, especially in conjunction with finite element analysis, has beco...
We propose an efficient numerical algorithm for computing deformations of “very ” soft tissues (such...
We present a reduced order finite element (FE) algorithm suitable for real-time nonlinear simulation...
International audienceMany applications in biomedical engineering and surgical simulators require ef...
Abstract. Realistic deformation of computer-simulated anatomical structures is computationally inten...
International audienceThis chapter presents different algorithms for modeling soft tissue deformatio...
The complexity of most surgical models has not allowed interactive simulations on standard computers...
The complexity of most surgical models has not allowed interactive simulations on standard computers...
The complexity of most surgical models has not allowed interactive simulations on standard computers...
International audienceThe complexity of most surgical models has not allowed interactive simulations...
In the 80's, biomechanicians were asked to work on Computer Aided Surgery applications since orthopa...
The reaction of soft tissue to applied forces can be calculated with biomechanical simulation algori...
Soft tissue modelling plays a significant role in surgery simulation as well as surgical procedure p...
This paper presents a numerical method for interactive (real-time) simulations, which considerably i...
Abstract. We present our systematic efforts in advancing the computational performance of physically...
The use of biomechanical modelling, especially in conjunction with finite element analysis, has beco...
We propose an efficient numerical algorithm for computing deformations of “very ” soft tissues (such...
We present a reduced order finite element (FE) algorithm suitable for real-time nonlinear simulation...
International audienceMany applications in biomedical engineering and surgical simulators require ef...
Abstract. Realistic deformation of computer-simulated anatomical structures is computationally inten...
International audienceThis chapter presents different algorithms for modeling soft tissue deformatio...
The complexity of most surgical models has not allowed interactive simulations on standard computers...
The complexity of most surgical models has not allowed interactive simulations on standard computers...
The complexity of most surgical models has not allowed interactive simulations on standard computers...
International audienceThe complexity of most surgical models has not allowed interactive simulations...
In the 80's, biomechanicians were asked to work on Computer Aided Surgery applications since orthopa...
The reaction of soft tissue to applied forces can be calculated with biomechanical simulation algori...
Soft tissue modelling plays a significant role in surgery simulation as well as surgical procedure p...
This paper presents a numerical method for interactive (real-time) simulations, which considerably i...
Abstract. We present our systematic efforts in advancing the computational performance of physically...
The use of biomechanical modelling, especially in conjunction with finite element analysis, has beco...