MA4245 Mathematical Foundations of Galerkin Methods

Course Learning Outcomes

• Convergence, consistency, stability, and the Lax Equivalence theorem
• Function spaces for vectors such as Sobolev and Hilbert spaces
• Approximation of functions via Lagrange interpolation and the importance of selecting the interpolation points wisely
• Differentiation functions via Lagrange interpolation approximations
• Integration of functions and their derivatives via Lagrange interpolation
• Construction of mass, differentiation, and Laplacian matrices in weak and strong form on the reference element
• Using these reference element matrices to construct global representations
• Using the global representations of the matrices to construct approximations for partial differential equations including those in one- and two-dimensions.
• Comprehension of the differences between hyperbolic, elliptic, and parabolic partial differential equations
• Application of these methods for solving systems of linear and nonlinear partial differential equations