Difference between revisions of "Projection based MOR"

Revision as of 17:11, 12 March 2013

The basic idea of almost all the model order reduction (MOR) methods is to find a subspace $S_1$ which approximates the manifold where the state vector Failed to parse (syntax error): {\bf x}(t) resides. Afterwards, Failed to parse (syntax error): {\bf x}(t) is approximated by a vector Failed to parse (syntax error): \tilde{\bf x}(t) in $S_1$. The reduced model is produced by Petrov-Galerkin projection onto a subspace $S_2$, or by Galerkin projection onto the same subspace $S_1$ .

We use the system Failed to parse (syntax error): E \frac{d{\bf x}}{dt}=A {\bf x}+B {\bf u}(t), \quad {\bf y}(t)=C{\bf x}+D{\bf u}(t).

as an example to explain the basic idea. Assuming that an orthonormal basis $V=(v_1,v_2, \ldots, v_q)$ of the subspace $S_1$ has been found, then the approximation Failed to parse (syntax error): \tilde{\bf x}(t) in $S_1$ can be represented by the basis as Failed to parse (syntax error): \tilde{\bf x}(t)=V{\bf z}(t) . Therefore Failed to parse (syntax error): {\bf x}(t) can be approximated by Failed to parse (syntax error): {\bf x}(t) \approx V{\bf z}(t) . Here ${\bf z}$ is a vector of length $q \ll n$.

Once Failed to parse (syntax error): {\bf z}(t) is computed, we can get an approximate solution Failed to parse (syntax error): \tilde{\bf x}(t)=V{\bf z}(t) for Failed to parse (syntax error): {\bf x}(t) . The vector Failed to parse (syntax error): {\bf z}(t) can be computed from the reduced model which is derived by the following two steps.

@@ Line 1: / Line 1: @@
+[[Category:method]]
 The basic idea of almost all the model order reduction (MOR) methods is to
 find a subspace <math>S_1</math> which approximates the manifold where the state
@@ Line 5: / Line 7: @@
 We use the system
 <math>
-$E \frac{d{\bf x}}{dt}=A {\bf x}+B {\bf u}(t)$, \\
+E \frac{d{\bf x}}{dt}=A {\bf x}+B {\bf u}(t), \quad
-${\bf y}(t)=C{\bf x}+D{\bf u}(t)$.
+{\bf y}(t)=C{\bf x}+D{\bf u}(t).
 </math>