A space-time finite element method for fractional wave problems
Provides rigorous numerical analysis for a class of fractional PDEs, benefiting researchers in computational fractional calculus.
The paper develops and analyzes a space-time finite element method for fractional wave problems, proving stability and optimal convergence rates, including for solutions with singularity at t=0 using graded grids.
This paper analyzes a space-time finite element method for fractional wave problems. The method uses a Petrov-Galerkin type time-stepping scheme to discretize the time fractional derivative of order $ γ$ ($1<γ<2$). We establish the stability of this method, and derive the optimal convergence in the $ H^1(0,T;L^2(Ω)) $-norm and suboptimal convergence in the discrete $ L^\infty(0,T;H_0^1(Ω)) $-norm. Furthermore, we discuss the performance of this method in the case that the solution has singularity at $ t= 0 $, and show that optimal convergence rate with respect to the $ H^1(0,T;L^2(Ω)) $-norm can still be achieved by using graded grids in the time discretization. Finally, numerical experiments are performed to verify the theoretical results.