LMIs in Control/SolutionInTermsofRiccatiInequalities: Difference between revisions

Let us now come back to the H∞-problem by output feedback control. This amounts to finding the matrices ${\displaystyle (A_K,B_K,C_K,D_K)}$ such that the conditions K stabilizes P and achieves ${\displaystyle \overline{S}(P,K{)}_{\mathrm{\infty }}<1}$. are satisfied. We proceed as in the state-feedback problem. We use the Bounded Real Lemma to rewrite the H∞ norm bound into the solvability of a Riccati inequality, and we try to eliminate the controller parameters to arrive at verifiable conditions.

Matrices to controller that solve the the H∞-problem by output feedback control

${\displaystyle (A_K,B_K,C_K,D_K)}$

Following matrices are needed as Inputs:.

${\displaystyle (A_K,B_K,C_K,D_K)}$.

${\displaystyle (A,B_1,B_2,C_1,C_2)}$.

In control systems theory, many analysis and design problems are closely related to Riccati algebraic equations or inequalities. Find X and Y

There exist ${\displaystyle A_K,B_K,C_K,D_K}$ that solve the output-feedback H∞ problem (K that stabilizes P and achieves ${\displaystyle \overline{S}(P,K{)}_{\mathrm{\infty }}<1}$) if and only if there exist X and Y that satisfy the two ARIs

${\displaystyle A^{T}X+XA+X{B}_1{B}_1^{T}X+C_1^T-C_2^T{C}_2<0}$

${\displaystyle AY+Y{A}^T+Y{C}_1^T{C}_{1}Y+B_1{B}_1^T-B_2{B}_2^T<0}$

and the coupling condition

${\displaystyle \begin{array}{c}{\displaystyle \begin{array}{c}\left[\begin{array}{cc}X& I\\ I& Y\end{array}\right]<0\end{array}}\\ \end{array}}$

Let U and V be square and non-singular matrices with ${\displaystyle U{V}^T=I-XY}$, and set ${\displaystyle L=-X^{-1}{C}_2^T}$ ,${\displaystyle F:=-B_2^T{Y}^{-1}}$. Then ${\displaystyle A_K,B_K,C_K}$ as defined in

${\displaystyle A_k=-U^{-1}[A^T+X(A+L{C}_2+B_{2}F)Y+X(B_1+L{D}_{21})B_1^T+C_1^T(C_1+D_{12}F)Y]V^{-T}}$

${\displaystyle B_K=U^{-1}XL}$

${\displaystyle C_K=FY{V}^{-T}}$

lead to a controller K that stabilizes P and achieves ${\displaystyle \overline{S}(P,K{)}_{\mathrm{\infty }}<1}$

• http://control.asu.edu/MAE598_frame.htm LMI Methods in Optimal and Robust Control- A course on LMIs in Control by Matthew Peet.
• https://https://arxiv.org/abs/1903.08599/ LMI Properties and Applications in Systems, Stability, and Control Theory] - A List of LMIs by Ryan Caverly and James Forbes.
• https://web.stanford.edu/~boyd/lmibook/ LMIs in Systems and Control Theory- A downloadable book on LMIs by Stephen Boyd.

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