LMIs in Control/pages/Delay Dependent Time-Delay Stabilization

Stabilization of Time-Delay Systems - Delay Dependent Case

Suppose, for instance, there was a system where a time-delay was introduced. In that instance, stabilization would have to be done in a different manner. The following example demonstrates how one can stabilize such a system while being dependent on the delay.

For this particular problem, suppose that we were given the time-delayed system in the form of:

${\displaystyle {\begin{aligned}{\begin{cases}{\dot {x}}(t)&=Ax(t)+A_{d}(t-d)+Bu(t),\\x(t)&=\phi (t),t\in [0,d],0<d\leq {\bar {d}},\\\end{cases}}\end{aligned}}}$

where

${\displaystyle {\begin{aligned}&A{\text{, }}{A_{d}}\in \mathbb {R} ^{n\times n}{\text{, }}{B}\in \mathbb {R} ^{n\times r}{\text{ are the system coefficient matrices,}}\\&\phi (t){\text{ is the initial condition,}}\\&d{\text{ represents the time-delay, and}}\\&{\bar {d}}{\text{ is a known upper-bound of }}d\\\end{aligned}}}$

Then the LMI for determining the Time-Delay System for the Delay-Dependent case would be obtained as described below.

In order to obtain the LMI, we need the following 3 matrices: ${\displaystyle A{\text{, }}{A_{d}}{\text{, and }}B}$.

Suppose - for the time-delayed system given above - we were asked to design a memoryless feedback control law where ${\displaystyle u(t)=Kx(t)}$ such that the closed-loop system:

${\displaystyle {\begin{aligned}{\begin{cases}{\dot {x}}(t)&=(A+BK)x(t)+A_{d}(t-d),\\x(t)&=\phi (t),t\in [0,d],0<d\leq {\bar {d}},\\\end{cases}}\end{aligned}}}$

is simultaneously both uniform and asymptotically stable, then the system would be stabilized as follows.

From the given pieces of information, it is clear that the optimization problem only has a solution if there exists a scalar ${\displaystyle 0<\beta <1}$, a symmetric matrix ${\displaystyle X>0}$ and a matrix ${\displaystyle W}$ that satisfy the following:

${\displaystyle {\begin{aligned}{\begin{bmatrix}\Phi (X,W)&&{\bar {d}}(X{A^{T}}+{W^{T}}{B^{T}})&&{\bar {d}}X{A_{d}^{T}}\\{\bar {d}}(AX+BW)&&-{\bar {d}}{\beta }I&&0\\{\bar {d}}{A_{d}}X&&0&&-{\bar {d}}(1-\beta )I\end{bmatrix}}&<0\\\end{aligned}}}$

where${\displaystyle \Phi (X,W)=X{(A+{A_{d}})^{T}}+(A+{A_{d}})X+BW+{W^{T}}{B^{T}}+{\bar {d}}{A_{d}}{A_{d}^{T}}}$

Given the resulting stabilizing control gain matrix ${\displaystyle K=WX^{-1}}$, it can be observed that the matrix is asymptotically stable from the time-delay system where this gain matrix was derived.

• Example Code - A GitHub link that contains code (titled "DelayDependentTimeDelay.m") that demonstrates how this LMI can be implemented using MATLAB-YALMIP.

• Delay Independent Time-Delay Stabilization - Equivalent LMI for delay-independent time-delay stabilization.

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.
• LMIs in Control Systems: Analysis, Design and Applications - A book co-authored by Guang-Ren Duan and Hai-Hua Yu.