Reduced Basis PMOR method

The Reduced Basis Method (RBM) we present here is applicable to static and time-dependent linear PDEs.

Time-Independent PDEs

The typical model problem of the RBM consists of a parametrized PDE stated in weak form with bilinear form $a (\cdot, \cdot; μ)$ and linear form $f (\cdot; μ)$ . The parameter $μ$ is considered within a domain $𝒟$ and we are interested in an output quantity $s (μ)$ which can be expressed via a linear functional of the field variable $l (\cdot; μ)$ .

The exact, infinite-dimensional formulation, indicated by the superscript e, is given by

${\begin{cases} For μ \in 𝒟 \subset ℝ^{P}, evaluate \\ s^{e} (μ) = l (u^{e} (μ); μ), \\ where u^{e} (μ) \in X^{e} (Ω) satisfies \\ a (u^{e} (μ), v; μ) = f (v; μ), \forall v \in X^{e} . \end{cases}$

We assume a large-scale discretization to be given, such that we consider

${\begin{cases} For μ \in 𝒟 \subset ℝ^{P}, evaluate \\ s (μ) = l (u (μ); μ), \\ where u (μ) \in X (Ω) satisfies \\ a (u (μ), v; μ) = f (v; μ), \forall v \in X . \end{cases}$

The underlying assumption of the RBM is that the parametrically induced manifold $ℳ = {u (μ) | μ \in 𝒟}$ can be approximated by a low dimensional space $V_{N}$ .

It also applies the concept of an offline-online decomposition, in that a large pre-processing offline cost is acceptable in view of a very low online cost (of a reduced order model) for each input-output evaluation, when in a many-query or real-time context.

The essential assumption which allows the offline-online decomposition is that there exists an affine parameter dependence

$a (w, v; μ) = \sum_{q = 1}^{Q} Θ_{a}^{q} (μ) a^{q} (w, v)$

$f (v; μ) = \sum_{q = 1}^{Q^{f}} Θ_{f}^{q} (μ) f^{q} (v) .$

The Lagrange Reduced Basis space is established by iteratively choosing Lagrange parameter samples

$S_{N} = {μ^{1}, . . ., μ^{N}}$

and considering the associated Lagrange RB spaces

$V_{N} = span {u^{𝒩} (μ^{n}), 1 \leq n \leq N}$

in a greedy sampling. This leads to hierarchical RB spaces: $V_{1} \subset V_{2} \subset . . . \subset V_{N_{m a x}}$ .

We then consider the galerkin projection onto the RB-space $V_{N}$

${\begin{cases} For μ \in 𝒟 \subset ℝ^{P}, evaluate \\ s_{N} (μ) = f (u_{N} (μ)), \\ where u_{N} (μ) \in V_{N} satisfies \\ a (u_{N} (μ), v; μ) = f (v), \forall v \in V_{N} \end{cases}$

The greedy sampling uses an error estimator $Δ_{N} (μ)$ which estimates (even rigorously, in some cases) the approximation error $‖ u (μ) - u_{N} (μ) ‖$ .

Let $Ξ$ denote a finite sample of $𝒟$ and set $S_{1} = {μ^{1}} and V_{1} = s p a n {u (μ^{1})}$ . For $N = 2, . . ., N_{m a x}$ , find $μ^{N} = {arg max}_{μ \in Ξ} Δ_{N - 1} (μ)$ , and then set $S_{N} = S_{N - 1} \cup μ^{N}, V_{N} = V_{N - 1} + s p a n {u (μ^{N})}$ .

Time-Dependent PDEs

When time is involved, it can be roughly considered as an usual parameter just as time-independent case. But more attention should be paid to the dynamics of the system and the stability is also a major concern, especially for the nonlinear case. Mostly, we use the same notation as time-independent case except the variable $t$ is added explicitly.

The exact, infinite-dimensional formulation, indicated by the superscript e, is given by

${\begin{cases} For μ \in 𝒟 \subset ℝ^{P}, t^{k} \in [0, T] evaluate \\ s^{e} (μ, t^{k}) = l (u^{e} (μ, t); μ), \\ where u^{e} (μ, t) \in X^{e} (Ω) satisfies \\ m (u^{e} (μ, t^{k}), v; μ) + Δ t a (u^{e} (μ, t^{k}), v; μ) = m (u^{e} (μ, t^{k - 1}), v; μ) + Δ t f (v; μ) u^{e} (μ, t^{k}), \forall v \in X^{e} . \end{cases}$

Here $m (\cdot, \cdot; μ)$ is also a bilinear form.

Assume a reference discretization form is given as follows,

${\begin{cases} For μ \in 𝒟 \subset ℝ^{P}, t^{k} \in [0, T] evaluate \\ s (μ, t^{k}) = l (u (μ, t); μ), \\ where u (μ, t) \in X_{𝒩} (Ω) satisfies \\ m (u (μ, t^{k}), v; μ) + Δ t a (u (μ, t^{k}), v; μ) = m (u (μ, t^{k - 1}), v; μ) + Δ t f (v; μ) u (μ, t^{k}), \forall v \in X_{𝒩} . \end{cases}$

The underlying assumption of the RBM is that the parametrically induced manifold $ℳ = {u (μ, t) | μ \in 𝒟}$ can be approximated by a low dimensional space $V_{N}$ .

To apply the offline-online decomposition, we assume they are affine parameter-dependent, i.e.

$m (w, v; μ) = \sum_{q = 1}^{Q_{m}} Θ_{m}^{q} (μ, t) m^{q} (w, v)$

$a (w, v; μ) = \sum_{q = 1}^{Q_{a}} Θ_{a}^{q} (μ, t) a^{q} (w, v)$

$f (v; μ) = \sum_{q = 1}^{Q_{f}} Θ_{f}^{q} (μ, t) f^{q} (v) .$

The Lagrange Reduced Basis space $V_{N}$ is usually established by POD-Greedy algorithm [3]. Then the following reduced model can be obtained by using Galerkin projection.

${\begin{cases} For μ \in 𝒟 \subset ℝ^{P}, t^{k} \in [0, T] evaluate \\ s (μ, t^{k}) = l (u_{N} (μ, t); μ), \\ where u_{N} (μ, t) \in X_{N} (Ω) satisfies \\ m (u_{N} (μ, t^{k}), v; μ) + Δ t a (u_{N} (μ, t^{k}), v; μ) = m (u_{N} (μ, t^{k - 1}), v; μ) + Δ t f (v; μ) u_{N} (μ, t^{k}), \forall v \in X_{N} . \end{cases}$

Note that the assumption of affine form can be relaxed in practice, then empirical interpolation [1] methods can be exploited for offline-online decomposition.

References

[1] M. Barrault, Y. Maday, N. Nguyen, and A. Patera, An `empirical interpolation' method: application to effcient reduced-basis discretization of partial differential equations, C. R. Math. Acad. Sci. Paris Series I, 339 (2004), 667-672.

[2] M. Grepl, Reduced--basis approximations and posteriori error estimation for parabolic partial differential equations, PhD thesis, MIT, 2005.

[3] B. Haasdonk and M. Ohlberger, Reduced basis method for finite volume approximations of parameterized linear evolution equations, Mathematical Modeling and Numerical Analysis, 42 (2008), 277-302.

[4] G. Rozza, D.B.P. Huynh, A.T. Patera Reduced Basis Approximation and a Posteriori Error Estimation for Affinely Parametrized Elliptic Coercive Partial Differential Equations, Arch Comput Methods Eng (2008) 15: 229–275.

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Martin Hess

Yongjin Zhang