Moment-matching method: Difference between revisions

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The moment-matching methods are also called the Krylov subspace methods^[1], as well as Padé approximation methods^[2]. They belongs to the Projection based MOR methods. These methods are applicable for non-parametric linear time invariant systems, often the descriptor systems, e.g.

${\displaystyle E\frac{dx(t)}{dt}=Ax(t)+Bu(t),y(t)=Cx(t),(1)}$

They are very efficient in many engineering applications, such as circuit simulation, Microelectromechanical systems (MEMS) simulation, etc..

The basic steps are as follows. First, the transfer function

${\displaystyle H(s)=Y(s)/U(s)=C(sE-A{)}^{-1}B}$

is expanded into a power series at an expansion point ${\displaystyle s_0\in \mathbb{ℂ}\cup \mathrm{\infty }}$.

Let ${\displaystyle s=s_0+\sigma }$, then, within the convergence radius of the series, we have

${\displaystyle H(s_0+\sigma )=C[(s_0+\sigma )E-A{]}^{-1}B}$

${\displaystyle =C[\sigma E+(s_{0}E-A){]}^{-1}B}$

${\displaystyle =C[I+\sigma (s_{0}E-A{)}^{-1}E{]}^{-1}[(s_{0}E-A){]}^{-1}B}$

${\displaystyle =C[I-\sigma (s_{0}E-A{)}^{-1}E+{\sigma }^2[(s_{0}E-A{)}^{-1}E{]}^2+\dots ]s_{0}E-A{)}^{-1}B}$

${\displaystyle =\sum _{i=0}^{\mathrm{\infty }}\underset{:=m_i(s_0)}{\underbrace{C[-(s_{0}E-A{)}^{-1}E{]}^i(s_{0}E-A{)}^{-1}B}}{\sigma }^i,}$

where ${\displaystyle m_i(s_0)}$ are called the moments of the transfer function about ${\displaystyle s_0}$ for ${\displaystyle i=0,1,2,\dots }$. If the expansion point is chosen as zero, then the moments simplify to ${\displaystyle m_i(0)=C(A^{-1}E{)}^i(-A^{-1}B)}$.

The goal in moment-matching model reduction is the construction of a reduced order system where some moments ${\displaystyle {\hat{m}}_i}$ of the associated transfer function ${\displaystyle \hat{H}}$ match some moments of the original transfer function ${\displaystyle H}$.

The matrices ${\displaystyle V}$ and ${\displaystyle W}$ for model order reduction can be computed from the vectors which are associated with the moments, for example, using a single expansion point ${\displaystyle s_0=0}$, by

${\displaystyle \text{<mrow data-mjx-texclass="ORD">range</mrow>}(V)=\text{<mrow data-mjx-texclass="ORD">span</mrow>}\{\tilde{B},(A^{-1}E{)}^2\tilde{B},\dots ,(A^{-1}E{)}^r\tilde{B}\},(2)}$

${\displaystyle \text{<mrow data-mjx-texclass="ORD">range</mrow>}(W)=\text{<mrow data-mjx-texclass="ORD">span</mrow>}\{C^T,E^T{A}^{-T}{C}^T,(E^T{A}^{-T}{)}^2{C}^T,\dots ,(E^T{A}^{-T}{)}^{r-1}{C}^T\},(3)}$

where ${\displaystyle \tilde{B}=-A^{-1}B}$.

The transfer function ${\displaystyle \hat{H}}$ of the reduced model has good approximation properties around ${\displaystyle s_0}$, which matches the first ${\displaystyle 2r}$ moments of ${\displaystyle H(s)}$ at ${\displaystyle s_0}$.

Using a set of ${\displaystyle k}$ distinct expansion points ${\displaystyle \{s_1,\cdots ,s_k\}}$, the reduced model obtained by, e.g.,

${\displaystyle \text{<mrow data-mjx-texclass="ORD">range</mrow>}(V)=\text{<mrow data-mjx-texclass="ORD">span</mrow>}\{(A-s_{1}E{)}^{-1}E\tilde{B},\dots ,(A-s_{k}E{)}^{-1}E\tilde{B}\},(4)}$

${\displaystyle \text{<mrow data-mjx-texclass="ORD">range</mrow>}(W)=\text{<mrow data-mjx-texclass="ORD">span</mrow>}\{E^T(A-s_{1}E{)}^{-T}{C}^T,\dots ,E^T(A-s_{k}E{)}^{-T}{C}^T\},(5)}$

matches the first two moments at each ${\displaystyle s_j}$, ${\displaystyle j=1,\dots ,k}$, see ^[3]. The reduced model is in the form as below

${\displaystyle W^{T}E\frac{dVz}{t}=W^{T}AVz+W^{T}Bu(t),\hat{y}(t)=CVz.}$

For the case of one expansion point in (2)(3), it can be seen that the columns of ${\displaystyle V}$, ${\displaystyle W}$ span Krylov subspaces which can easily be computed by Arnoldi or Lanczos methods. The matrices ${\displaystyle V}$ and ${\displaystyle W}$ in (4)(5) can be computed with the rational Krylov algorithm in^[3] or with the modified Gram-Schmidt process. In these algorithms only a few number of linear systems need to be solved, where matrix-vector multiplications are only used if using iterative solvers, which are simple to implement and the complexity of the resulting methods is roughly ${\displaystyle O(n{r}^2)}$ for sparse matrices ${\displaystyle A,E}$.

References