LMIs in Control/pages/Hinf-Optimal Filter

Hinf-Optimal Filter

The goal of optimal filtering is to design a filter that acts on the output ${\displaystyle 𝐳}$of the generalized plant and optimizes the transfer matrix from ${\displaystyle 𝐰}$to the filtered output.

Consider the continuous-time generalized LTI plant, with minimal state-space representation

${\displaystyle \dot{𝐱}=𝐀𝐱+{𝐁}_1𝐰,}$

${\displaystyle 𝐳={𝐂}_1𝐱+{𝐃}_{11}𝐰,}$

${\displaystyle 𝐲={𝐂}_2𝐱+{𝐃}_{21}𝐰,}$

where it is assumed that ${\displaystyle 𝐀}$is Hurwitz. A continuous-time dynamic LTI filter with state-space representation

${\displaystyle {\dot{𝐱}}_f={𝐀}_f{𝐱}_f+{𝐁}_f𝐲,}$

${\displaystyle \widehat{𝐳}={𝐂}_f{𝐱}_f+{𝐃}_f𝐲,}$

is designed to optimize the transfer function from ${\displaystyle 𝐰}$to ${\displaystyle \widetilde{𝐳}=𝐳-\widehat{𝐳}}$, which is given by

${\displaystyle \widetilde{𝐏}(s)={\widetilde{𝐂}}_1(s𝐈-\widetilde{𝐀}{)}^{-1}{\widetilde{𝐁}}_1+{\widetilde{𝐃}}_{11},}$

where

${\displaystyle \widetilde{𝐀}=\left[\begin{array}{cc}𝐀& \mathrm{𝟎}\\ {𝐁}_f{𝐂}_2& {𝐀}_f\end{array}\right],}$

${\displaystyle {\widetilde{𝐁}}_1=\left[\begin{array}{c}{𝐁}_1\\ {𝐁}_f{𝐃}_{21}\end{array}\right],}$

${\displaystyle {\widetilde{𝐂}}_1=\left[\begin{array}{cc}{𝐂}_1-{𝐃}_f{𝐂}_2& -{𝐂}_f\end{array}\right],}$

${\displaystyle {\widetilde{𝐃}}_{11}={𝐃}_{11}-{𝐃}_f{𝐃}_{21}.}$

Optimal Filtering seeks to minimize the given norm of the transfer function ${\displaystyle \widetilde{𝐏}(s).}$

Solve for ${\displaystyle {𝐀}_n\in {ℝ}^{n_x\times n_x},{𝐁}_n\in {ℝ}^{n_x\times n_y},{𝐂}_f\in {ℝ}^{n_z\times n_x},{𝐃}_f\in {ℝ}^{n_z\times n_y},𝐗,𝐘\in {\mathrm{\S }}^{n_x},}$and ${\displaystyle \gamma \in {ℝ}_{>0}}$ that minimize the objective function ${\displaystyle J(\gamma )=\gamma }$, subject to

${\displaystyle 𝐗,𝐘>0,}$

${\displaystyle 𝐘-𝐗>0,}$

${\displaystyle \left[\begin{array}{ccc}𝐘𝐀+{𝐀}^T𝐘+{𝐁}_n{𝐂}_2+{𝐂}_2^T{𝐁}_n^T& {𝐀}_n+{𝐂}_2^T{𝐁}_n^T+{𝐀}^T𝐗& {𝐘𝐁}_1+{𝐁}_n{𝐃}_{21}\\ *& {𝐀}_n+{𝐀}_n^T& {𝐗𝐁}_1+{𝐁}_n{𝐃}_{21}\\ *& *& -𝐈\end{array}\right]<0.}$

The optimal Hinf filter is recovered by the state-space matrices ${\displaystyle {𝐀}_f={𝐗}^{-1}{𝐀}_n}$and ${\displaystyle {𝐁}_f={𝐗}^{-1}{𝐁}_n.}$

The problem of optimal filtering can alternatively be formulated as a special case of synthesizing a dynamic output "feedback" controller for the generalized plant given by

${\displaystyle \dot{𝐱}=𝐀𝐱+{𝐁}_1𝐰,}$

${\displaystyle 𝐳={𝐂}_1𝐱+{𝐃}_{11}𝐰-𝐮,}$

${\displaystyle 𝐲={𝐂}_2𝐱+{𝐃}_{21}𝐰.}$

The synthesis method presented in this page takes advantage of the fact that the controller in this case is not a true feedback controller, as it only appears as a feedthrough term in the performance channel.

A list of references documenting and validating the LMI.

• LMI Methods in Optimal and Robust Control - A course on LMIs in Control by Matthew Peet.
• LMI Properties and Applications in Systems, Stability, and Control Theory - A List of LMIs by Ryan Caverly and James Forbes.
• LMIs in Systems and Control Theory - A downloadable book on LMIs by Stephen Boyd.

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