Parallel Computational Methods for 3D Simulation of a Parafoil with Prescribed Shape Changes

In this paper we describe parallel computational methods for 3D simulation of the dynamics and uid dynamics of a parafoil with prescribed, time-dependent shape changes. The mathematical model is based on the time-dependent, 3D Navier-Stokes equations governing the incompressible ow around the parafoil and Newton's law of motion governing the dynamics of the parafoil, with the aerodynamic forces acting on the parafoil calculated from the ow eld. The computational methods developed for these 3D simulations include a stabilized space-time nite element formulation to accommodate for the shape changes, special mesh generation and mesh moving strategies developed for this purpose, iterative solution techniques for the large, coupled nonlinear equation systems involved, and parallel implementation of all these methods on scalable computing systems such as the Thinking Machines CM-5. As an example, we report 3D simulation of a are maneuver in which the parafoil velocity is reduced by pulling down the aps. This simulation requires solution of over 3.6 million coupled, nonlinear equations at every time step of the simulation.