where ,, and form the K matrix as defined in below. This, therefore, means that the Regulator system can be re-written as:
With the above 9-matrix representation in mind, the we can now derive the controller needed for solving the problem, which in turn will be accomplished through the use of LMI's. Firstly, we will be taking our /state-feedback control and make some modifications to it. More specifically, since the focus is modeling for worst-case scenario of a given parameter, we will be modifying the LMI's such that the mixed / controller is polytopic.
/ Polytopic Controller for Quadrotor with Robotic Arm.
Recall that from the 9-matrix framework , and represent our process and sensor noises respectively and represents our input channel. Suppose we were interested in modeling noise across all three of these channels. Then the best way to model uncertainty across all three cases would be modifying the matrix to , where ( parameters, , and is a constant noise value). This, in turn results in our - matrices to be modifified to -
Using the LMI's given for optimal /-optimal state-feedback controller from Peet Lecture 11 as reference, our resulting polytopic LMI becomes:
+
CD=0
where i=1,..,k,& and and:
After solving for both the optimal and gain ratios as well as , we can then construct our worst-case scenario controller by setting our matrix (and consequently our matrices) to the highest value. This results in the controller:
1. An LMI-Based Approach for Altitude and Attitude Mixed H2/Hinf-Polytopic Regulator Control of a Quadrotor Manipulator by Aditya Ramani and Sudhanshu Katarey.