Difference between revisions of "Bilinear PMOR method"

Revision as of 08:02, 6 December 2011

The model reduction method we present here is applicable to linear parameter-varying (LPV) systems of the form

$\dot{x}(t)=Ax(t) + \sum_{i=1}^d p_i(t)A_i x(t)+B_0u_0(t),\quad y(t)=Cx(t),$

where $A,A_i \in \mathbb R^{n\times n}, B_0 \in \mathbb R^{n\times m}$ and $C \in \mathbb R^{p\times n}.$

The main idea is that the structure of the above type of systems is quite similar to so-called bilinear control systems. Although belonging to the class of nonlinear control systems, the latter exhibit many features of linear time-invariant systems. In more detail, a bilinear control system is given as follows

$\dot{x}(t)=Ax(t) + \sum_{i=1}^m N_i x(t) u_i(t) + B u(t),$

where $A,N \in \mathbb R^{n\times n}, B \in \mathbb R^{n\times m}$ and $C \in \mathbb R^{p\times n}.$

@@ Line 1: / Line 1: @@
+The model reduction method we present here is applicable to linear parameter-varying (LPV) systems of the form
-test
+<center>
+<math>
+\dot{x}(t)=Ax(t) + \sum_{i=1}^d p_i(t)A_i x(t)+B_0u_0(t),\quad y(t)=Cx(t),
+</math>
+</center>
+where
+<math>
+A,A_i \in \mathbb R^{n\times n}, B_0 \in \mathbb R^{n\times m}
+</math>
+and
+<math>  C \in \mathbb R^{p\times n}.
+</math>
+The main idea is that the structure of the above type of systems is quite similar to so-called bilinear control systems. Although belonging to the class of nonlinear control systems, the latter exhibit many features of linear time-invariant systems. In more detail, a bilinear control system is given as follows
+<center>
+<math>
+\dot{x}(t)=Ax(t) + \sum_{i=1}^m N_i x(t) u_i(t) + B u(t),
+</math>
+</center>
+where
+<math>
+A,N \in \mathbb R^{n\times n}, B \in \mathbb R^{n\times m}
+</math>
+and
+<math>  C \in \mathbb R^{p\times n}.
+</math>