We present a reconection-based Lagrangian+rezone(LR) method,in which connectivity of meshes can be changed in a rezone phase in order to handle geometric intersection.The method maintains more Lagrangian features of meshes than standard LR methods.Numerical examples demonstrate that the method is more robust for large defomations.It shows predictive capabilities of reconnection-based LR method.

According to the principles of Modeling & Simulation(M&S)and charactersitic of detonation system that final performances are determined by initial conditions,total uncertainties are sorted to three parts that varying along with initial conditions.It reveals how uncertainties are brought on and evolve from benchmark models to new models.Based on engineering practices and technology of verification & validation,a framework of quantification about uncertainty is brought forward in detonation simulation.An example is presented to demonstrate general idea in quantifying uncertainty of M&S.

Based on Noh's artificial viscosity with artificial heat flux method(Q & H),we present a Q & H scheme on arbitrary n-polygon meshes.Noh's Q & H on structured meshes is extended to unstructured meshes in two dimensions.Numerical results of Noh's problem and collision of two metals show that the Q&H method on unstructured meshes eliminates wall heating effectivly.