Parallel Adaptive Simulations of Dynamic Fracture Events
Engineering with Computers 2006
Publication Type: Paper
Finite element simulations of dynamic fracture problems usually require very fine discretizations in the vicinity of the propagating stress waves and advancing crack fronts, while coarser meshes can be used in the remainder of the domain. This need for a constantly evolving discretization poses several challenges, especially when the simulation is performed on a parallel computing platform. To address this issue, we present a parallel computational framework developed specifically for unstructured meshes. This framework allows dynamic adaptive refinement and coarsening of finite element meshes and also performs load balancing between processors. We demonstrate the capability of this framework, called ParFUM, using two-dimensional structural dynamic problems involving the propagation of elastodynamic waves and the spontaneous initiation and propagation of cracks through a domain discretized with triangular finite elements.
Sandhya Mangala, Terry Wilmarth, Sayantan Chakravorty, Nilesh Choudhury, Laxmikant V. Kale and Philippe H. Geubelle, Parallel Adaptive Simulations of Dynamic Fracture Events, Parallel Programming Laboratory, Department of Computer Science , University of Illinois, Urbana-Champaign, PPL Technical Report 06-15, Accepted for publication in Engineering with Computers, 2007.
- Sandhya Mangala
- Terry Wilmarth
- Sayantan Chakravorty
- Nilesh Choudhury
- Laxmikant Kale
- Philippe Geubelle