LMIs in Control/Click here to continue/Applications of Linear systems/Mixed H2-H∞ Optimal Voltage Control Design for Smart Transformer Low-Voltage Inverter

Smart transformers are often used in situations with variable loads such as the integration of renewable energy sources. This section examines a system of Linear Matrix Inequalities as analyzed by Wei Hu, Yu Shen, Zhichun Yang, and Huaidong Min in their paper for Mixed $H_{2}$ / $H_{\infty }$ Optimal Voltage Control Design for Smart Transformer Low-Voltage Inverter.

The System edit

State space modelling is used in order to develop a system that describes the inverter behavior.

{\begin{aligned}{\dot {x_{p}}}&=A_{p}x+B_{p1}v_{c}+B_{p2}w_{p}\\y&=C_{p}x_{p}\\\end{aligned}}

The system formulation for a simple inverter system draws directly from electric circuit theory. $A_{p}={\begin{bmatrix}-R/L&-1/L\\1/C&0\end{bmatrix}}$ $B_{p1}={\begin{bmatrix}1/L\\0\end{bmatrix}}$ $B_{p2}={\begin{bmatrix}0\\1/C\end{bmatrix}}$ $C_{p}={\begin{bmatrix}0&1\end{bmatrix}}$ where the above variables are defined as follows:

$R$ is the resistance
$L$ is the inductance
$C$ is the capacitance

This system is further augmented by adding multiple resonant controllers to ensure the system can reach zero steady-state error when tracking sinusoidal target outputs. The augmented system is then derived as follows:

{\begin{aligned}{\dot {x_{p}}}&=Ax+B_{1}v_{c}+B_{2}w_{p}+Ry^{*}\\y&=Cx\\\end{aligned}}

where

$A={\begin{bmatrix}A_{p}&0&0&&0&0\\-C_{p}&j\omega &0&...&0&0\\-C_{p}&0&-j\omega &&0&0\\&...&&...&&...\\-C_{p}&0&0&&j_{n}\omega &0\\-C_{p}&0&0&...&0&-j_{n}\omega \end{bmatrix}}$

$B_{1}={\begin{bmatrix}B_{p1}&0&0&\cdots &0&0\end{bmatrix}}^{T}$

$B_{2}={\begin{bmatrix}B_{p2}&0&0&\cdots &0&0\end{bmatrix}}^{T}$

$C={\begin{bmatrix}C_{p}&0&0&\cdots &0&0\end{bmatrix}}$

$R={\begin{bmatrix}0&1&1&\cdots &1&1\end{bmatrix}}$

The Data edit

The data required to solve this problem includes the values of resistance, inductance, capacitance, switch frequency, output peak voltage, and the DC link voltage.

The Optimization Problem edit

The optimization problem aims to minimize a combined $H_{2}$ / $H_{\infty }$ norm of the system as defined above. In order to accomplish this task, constraints and the objective must first be defined.

Objective: Combined $H_{2}$ / $H_{\infty }$ norm
Constraints: Closed-loop poles are restricted to a desired section of the complex plane,

The LMI: Mixed H₂-H_∞ Optimal Voltage Control edit

${\begin{aligned}{\begin{cases}&{\text{min}}\quad a\gamma +bTrace(M)\\&{\text{s.t.}}\quad {\begin{bmatrix}M&I\\I&W_{1}\end{bmatrix}}>0\\\\&\quad \quad {\begin{bmatrix}(AW_{1}-B_{1}V_{1})+(AW_{1}-B_{1}V_{1})^{T}&W_{1}&V_{1}^{T}\\W_{1}&-Q_{inv}&0\\V_{1}&0&-R^{-1}\end{bmatrix}}<0\\\\&\quad \quad AX+B_{1}W+(AX+B_{1}W)^{T}+BB^{T}<0\\\\&\quad \quad L_{j}\otimes W_{3}+M_{j}\otimes (AW_{3}+B_{1}V_{3})+M_{j}^{T}\otimes (AW_{3}+B_{1}V_{3})^{T}<0,j=1,2,3\\\\&\quad \quad {\begin{bmatrix}(AW_{2}-B_{1}V_{2})+(AW_{2}-B_{1}V_{2})^{T}&B_{2}&W_{2}C^{T}\\B_{2}^{T}&-\gamma I&0\\CW_{2}&0&-\gamma I\end{bmatrix}}<0\\\\\end{cases}}\\\end{aligned}}$

In the above LMIs, the coefficients a and b represent the weighting factor applied to the $H_{2}$ and $H_{\infty }$ norms respectively. R is some given positive-definite matrix.

Conclusion edit

Mixed $H_{2}$ / $H_{\infty }$ optimal control can be effectively used to design efficient and useful smart transformers.

Implementation edit

This LMI can be implemented using MATLAB when combined with YALMIP and an LMI solver such as SeDuMi.

Related LMIs edit

Mixed H2-H∞ Satellite Attitude Control

External Links edit

[1] – Mixed H2/H∞ Optimal Voltage Control Design for Smart Transformer Low-Voltage Inverter – Wei Hu, Yu Shen, Zhichun Yang, and Huaidong Min
[2] - LMIs in Control Systems: Analysis, Design, and Applications – Guang-Ren Duan and Hai-Hua Yu
LMI Methods in Optimal and Robust Control - A course on LMIs in Control by Matthew Peet.