ANALYSIS OF THE [L, L, L] LEAST-SQUARES FINITE ELEMENT METHOD FOR INCOMPRESSIBLE OSEEN-TYPE PROBLEMS

In this paper we analyze several first-order systems of Oseen-type equations that are obtained from the time-dependent incompressible NavierStokes equations after introducing the additional vorticity and possibly total pressure variables, time-discretizing the time derivative and linearizing the nonlinear terms. We apply the [L, L, L] least-squares finite element scheme to approximate the solutions of these Oseen-type equations assuming homogeneous velocity boundary conditions. All of the associated least-squares energy functionals are defined to be the sum of squared L norms of the residual equations over an appropriate product space. We first prove that the homogeneous least-squares functionals are coercive in the H × L × L norm for the velocity, vorticity, and pressure, but only continuous in the H ×H ×H norm for these variables. Although equivalence between the homogeneous least-squares functionals and one of the above two product norms is not achieved, by using these a priori estimates and additional finite element analysis we are nevertheless able to prove that the least-squares method produces an optimal rate of convergence in the H norm for velocity and suboptimal rate of convergence in the L norm for vorticity and pressure. Numerical experiments with various Reynolds numbers that support the theoretical error estimates are presented. In addition, numerical solutions to the time-dependent incompressible NavierStokes problem are given to demonstrate the accuracy of the semi-discrete [L, L, L] least-squares finite element approach.