Abstract
The onerous task of repeatedly resolving certain parametrized partial
differential equations (pPDEs) in, e.g. the optimization context, makes it
imperative to design vastly more efficient numerical solvers without
sacrificing any accuracy. The reduced basis method (RBM) presents itself as
such an option. With a mathematically rigorous error estimator, RBM seeks a
surrogate solution in a carefully-built subspace of the parameter-induced high
fidelity solution manifold. It can improve efficiency by several orders of
magnitudes leveraging an offline-online decomposition procedure. However, this
decomposition, usually through the empirical interpolation method (EIM) when
the PDE is nonlinear or its parameter dependence nonaffine, is either
challenging to implement, or severely degrading to the online efficiency.
In this paper, we augment and extend the EIM approach in the context of
solving pPDEs in two different ways, resulting in the Reduced Over-Collocation
methods (ROC). These are stable and capable of avoiding the efficiency
degradation inherent to a direct application of EIM. There are two ingredients
of these methods. First is a strategy to collocate at about twice as many
locations as the number of bases for the surrogate space. The second is an
efficient approach for the strategic selection of the parameter values to build
the reduced solution space for which we study two choices, a recent empirical
L1 approach and a new indicator based on the reduced residual. Together, these
two ingredients render the schemes, L1-ROC and R2-ROC, online efficient and
immune from the efficiency degradation of EIM for nonlinear and nonaffine
problems offline and online. Numerical tests on three different families of
nonlinear problems demonstrate the high efficiency and accuracy of these new
algorithms and their superior stability performance.