Balanced Truncation

Balanced Truncation is an important projection model reduction method which delivers high quality reduced models by making an extra effort in choosing the projection subspaces.

Derivation

A stable minimal (controllable and observable) system $\Sigma$ , realized by $(A,B,C,D)$

$\dot{x} = Ax + Bu$

$y = Cx + Du$

is called balanced^[1], if the systems Controllability Gramian and Observability Gramian, the solutions $W_C$ and $W_O$ of the Lyapunov equations

$AW_C+W_CA^T=-BB^T$

$A^TW_O+W_OA=-C^TC$

respectively, satisfy $W_C=W_O=diag(\sigma_1,\dots,\sigma_n)$ with $\sigma_1\geq\sigma_2\geq \dots\geq\sigma_n>0$ . Since in general, the spectrum of $W_CW_O$ are the squared Hankel Singular Values for such a balanced system, they are given by: $\sqrt{\lambda(W_CW_O)} = \{\sigma_1,\dots,\sigma_n\}$ .

An arbitrary system $(A,B,C,D)$ can be transformed into a balanced system $(\tilde{A},\tilde{B},\tilde{C},\tilde{D})$ via a state-space transformation:

$(\tilde{A},\tilde{B},\tilde{C},\tilde{D})= (TAT^{-1},TB,CT^{-1},D).$

This transformed system has balanced Gramians $W_C=T\tilde{W_C}T^T$ and $W_O=T^{-T}\tilde{W_O}T^{-1}$ which are equal and diagonal. The balanced systems states are ordered (descendingly) by how controllable and observable they are, thus allowing a partion of the form:

$(\tilde{A},\tilde{B},\tilde{C},\tilde{D})= \left (\begin{bmatrix}\tilde{A}_{11} & \tilde{A}_{12}\\ \tilde{A}_{21} & \tilde{A}_{22}\end{bmatrix},\begin{bmatrix}\tilde{B}_1\\\tilde{B}_2\end{bmatrix},\begin{bmatrix} \tilde{C}_1 &\tilde{C}_2 \end{bmatrix},\tilde{D}\right)$ .

By truncating the discardable states, the truncated reduced system is then given by $\hat{\Sigma}=(\tilde{A}_{11},\tilde{B}_1,\tilde{C}_1,\tilde{D})$ .

Implementation: SR Method

The necessary balancing transformation can be computed by the SR Method^[2]. First, the Cholesky factors of the gramians $W_C=S^TS,\; W_O=R^TR$ are computed. Next, the Singular Value Decomposition of $SR^T\;$ is computed:

$SR^T= U\Sigma V^T.$

Now, partitioning $U,V$ , for example based on the Hankel singuar Values, gives

$SR^T= \begin{bmatrix} U_1 U_2 \end{bmatrix} \begin{bmatrix} \Sigma_1 & \\ & \Sigma_2\end{bmatrix} \begin{bmatrix} V_1^T\\V_2^T\end{bmatrix}.$

The truncation of discardable partitions $U_2,V^T_2,\Sigma_2$ results in the reduced order model $(P^TAQ,P^TB,CQ,D)\;$ where

$P=R^T V_1\Sigma_1^{-\frac{1}{2}},$

$Q= S^T U_1 \Sigma_1^{-\frac{1}{2}}.$

$Q^TP=I_r$ makes $QP^T$ an oblique projector and hence Balanced Trunctation a Petrov-Galerkin projection method. The reduced model is stable with Hankel Singular Values given by $\sigma_1,\dots,\sigma_r$ , where r is the order of the reduced system. It is possible to choose $r$ via the computable error bound^[3]: