LMIs in Control/pages/Deduced LMI Conditions for H-infinity Index
H-infinity Index Deduced LMI
Although the KYP Lemma, also known as the Bounded Real Lemma, is a basic condition to evaluate an upper bound on the H∞, the verification of the bound on the H∞-gain of the system can be done via the deduced condition.
The System
[edit | edit source]A state-space representation of a linear system as given below:
where , and are the system state, output, and the disturbance vector respectively. The transfer function of such a system can be evaluated as:
The Data
[edit | edit source]Number of states n, number of outputs m and number of external noise channels r need to be known. Moreover, the system matrices A,B,C,D are also required to be known.
The Feasibility LMI
[edit | edit source]For an arbitrary , the transfer function G(s) satisfies
if and only if there exists a symmetric matrix X > 0 and a matrix such that:
where:
The above LMI can be combined with the bisection method to find minimum to find the minimum upper bound on the H∞ gain of .
Conclusion:
[edit | edit source]If there is a feasible solution to the aforementioned LMI, then the upper bounds the infinity norm of the system G(s).
Implementation
[edit | edit source]To solve the feasibility LMI, YALMIP toolbox is required for setting up the feasibility problem, and SeDuMi is required to solve the problem. The following link showcases an example of the feasibility problem:
https://github.com/smhassaan/LMI-Examples/blob/master/Deduced_hinf_example.m
Related LMIs
[edit | edit source]External Links
[edit | edit source]A list of references documenting and validating the LMI.
- LMIs in Control Systems: Analysis, Design and Applications - by Guang-Ren Duan and Hai-Hua Yu, CRC Press, Taylor & amp; Francis Group, 2013, Section 5.2.2 pp. 153–156.