LMIs in Control/Click here to continue/Controller synthesis/Quadratically Stabilizing Controllers with Parametric Norm-Bounded Uncertainty

If the system is quadratically stable, then there exists some $$\mu \geq 0, P > 0,$$ and $$Z$$ such that the LMI is feasible. The $$Z$$ and $$P$$ matrices can also be used to create a quadratically stabilizing controller.

The System


\begin{align} \dot x(t)&=Ax(t)+Bu(t)+Mp(t),&&p(t) = \Delta (t)q(t),\\ q(t) &= Nx(t)+Qp(t)+D_{12}u(t),&&\Delta \in \mathbf{\Delta} \; := \{\Delta \in \mathbb{R}^{n \times n} : \| \Delta \| \leq 1 \}\\ \end{align}$$

The Data
The matrices $$ A,B,M,N,Q,D_{12} $$.

The LMI:


\begin{align} \text{Find} \; &P>0,\mu \geq 0, \text{ and } Z:\\ \begin{bmatrix} AP+BZ+PA^T+Z^TB^T & PN^T+Z^TD_{12}^T \\ NP+D_{12}Z & 0\end{bmatrix} + \mu \begin{bmatrix} MM^T & MQ^T \\ QM^T & QQ^T - I \end{bmatrix} < 0\\ \end{align}$$

Conclusion:
There exists a controller for the system with $$ u(t) = Kx(t) $$ where $$ K = ZP^{-1} $$ is the quadratically stabilizing controller, if the above LMI is feasible.

Implementation
https://github.com/mcavorsi/LMI

Related LMIs
H-infinity Optimal Quadratically Stabilizing Controllers with Parametric Norm-Bounded Uncertainty

Stabilizing State-Feedback Controllers with Structured Norm-Bounded Uncertainty

Optimal State-Feedback Controllers with Structured Norm-Bounded Uncertainty