Synthetic parametric model: Difference between revisions

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Introduction

On this page you will find a synthetic parametric model for which one can easily experiment with different system orders ${\displaystyle n}$, values of the parameter ${\displaystyle \epsilon }$, as well as different poles and residues.

Also, the decay of the Hankel singular values can be changed indirectly through the parameter ${\displaystyle \epsilon }$.

Model description

The parameter ${\displaystyle \epsilon }$ scales the real part of the system poles, that is, ${\displaystyle p_i=\epsilon a_i+j{b}_i(j^2=-1)}$. For a system in pole-residue form

${\displaystyle H(s,\epsilon )={\displaystyle \sum _{i=1}^n}\frac{r_i}{s-p_i}={\displaystyle \sum _{i=1}^n}\frac{r_i}{s-(\epsilon a_i+j{b}_i)}}$

we can write down the state-space realization

${\displaystyle H(s,\epsilon )=\hat{C}(sI-\epsilon {\hat{A}}_{\epsilon }-{\hat{A}}_0{)}^{-1}\hat{B}+D}$

with system matrices defined as

${\displaystyle \epsilon {\hat{A}}_{\epsilon }+{\hat{A}}_0=\epsilon \left[\begin{array}{ccc}{a}_1& & \\ & \ddots & \\ & & a_n\end{array}\right]+\left[\begin{array}{ccc}j{b}_1& & \\ & \ddots & \\ & & j{b}_n\end{array}\right],}$

${\displaystyle \hat{B}=[1,\dots ,1{]}^T,\hat{C}=[r_1,\dots ,r_n],D=0.}$

Notice that the system matrices have complex entries.

For simplicity, assume that ${\displaystyle n}$ is even, ${\displaystyle n=2k}$, and that all system poles are complex and ordered in complex conjugate pairs, i.e.

${\displaystyle p_1=\epsilon a_1+j{b}_1,p_2=\epsilon a_1-j{b}_1,\dots ,p_{n-1}=\epsilon a_k+j{b}_k,p_n=\epsilon a_k-j{b}_k,}$

and the residues also form complex conjugate pairs

${\displaystyle r_1=c_1+j{d}_1,r_2=c_1-j{d}_1,\dots ,r_{n-1}=c_k+j{d}_k,r_n=c_k-j{d}_k.}$

Then a realization with matrices having real entries is given by

${\displaystyle A_{\epsilon }=\left[\begin{array}{ccc}{A}_{\epsilon ,1}& & \\ & \ddots & \\ & & A_{\epsilon ,k}\end{array}\right],A_0=\left[\begin{array}{ccc}{A}_{0,1}& & \\ & \ddots & \\ & & A_{0,k}\end{array}\right],B=\left[\begin{array}{c}{B}_1\\ ⋮\\ B_k\end{array}\right],C=\left[\begin{array}{ccc}{C}_1& \cdots & C_k\end{array}\right],D=0,}$

with ${\displaystyle A_{\epsilon ,i}=\left[\begin{array}{cc}{a}_i& 0\\ 0& a_i\end{array}\right]}$, ${\displaystyle A_{0,i}=\left[\begin{array}{cc}0& b_i\\ -b_i& 0\end{array}\right]}$, ${\displaystyle B_i=\left[\begin{array}{c}2\\ 0\end{array}\right]}$, ${\displaystyle C_i=\left[\begin{array}{cc}{c}_i& d_i\end{array}\right]}$.

Numerical values

We construct a system of order ${\displaystyle n=100}$. The numerical values for the different variables are

• ${\displaystyle a_i}$ equally spaced in ${\displaystyle [-10^3,-10]}$,

• ${\displaystyle b_i}$ equally spaced in ${\displaystyle [10,10^3]}$,

• ${\displaystyle c_i=1}$,

• ${\displaystyle d_i=0}$,

• ${\displaystyle \epsilon }$${\displaystyle \in [1/50,1]}$.

In MATLAB, the system matrices are easily formed as follows:

 n = 100;
 a = -linspace(1e1,1e3,n/2).';   b = linspace(1e1,1e3,n/2).';
 c = ones(n/2,1);                d = zeros(n/2,1);
 aa(1:2:n-1,1) = a;              aa(2:2:n,1) = a;
 bb(1:2:n-1,1) = b;              bb(2:2:n-2,1) = 0;
 Ae = spdiags(aa,0,n,n);
 A0 = spdiags([0;bb],1,n,n) + spdiags(-bb,-1,n,n);
 B = 2*sparse(mod([1:n],2)).';
 C(1:2:n-1) = c.';               C(2:2:n) = d.';   C = sparse(C);

The above system matrices ${\displaystyle A_{\epsilon },A_0,B,C}$ are also available in MatrixMarket format Synth_matrices.tar.gz.

Plots

We plot the frequency response ${\displaystyle H(s,\epsilon )=C(sI-\epsilon A_{\epsilon }-A_0{)}^{-1}B}$ and poles for parameter values ${\displaystyle \epsilon \in [1/50,1/20,1/10,1/5,1/2,1]}$.

In MATLAB, the plots are generated using the following commands:

 r(1:2:n-1,1) = c+1j*d;     r(2:2:n,1) = c-1j*d;
 ep = [1/50; 1/20; 1/10; 1/5; 1/2; 1];                       % parameter epsilon
 jw = 1j*linspace(0,1.2e3,5000).';                           % frequency grid
 for j = 1:length(ep)
   p(:,j) = [ep(j)*a+1j*b; ep(j)*a-1j*b];                    % poles
   [jww,pp] = meshgrid(jw,p(:,j));
   Hjw(j,:) = (r.')*(1./(jww-pp));                           % freq. resp.
 end
 figure,  loglog(imag(jw),abs(Hjw),'LineWidth',2)
          axis tight,    xlim([6 1200])
          xlabel('frequency (rad/sec)')
          ylabel('magnitude')
          title('Frequency response for different \epsilon')
 figure,  plot(real(p),imag(p),'.')
          title('Poles for different \epsilon')

Other interesting plots result for small values of the parameter. For example, for ${\displaystyle \epsilon =1/100,1/1000}$, the peaks in the frequency response become more pronounced, since the poles move closer to the imaginary axis.

Next, for ${\displaystyle \epsilon \in [1/50,1/20,1/10,1/5,1/2,1]}$, we also plot the decay of the Hankel singular values. Notice that for small values of the parameter, the decay of the Hankel singular values is very slow.

Contact information:

User:Ionita 14:38, 29 November 2011 (UTC)