Peek Inductor: Difference between revisions

Help

Note: This page has not been verified by our editors.

Description: Spiral Inductor PEEC Model

The description of the PEEC model of a spiral inductor can be found in LiKamon.pdf.

The complex impedance is:

${\displaystyle Z(w)=Resis(w)+i*w*Induc(w)=G(i*w{)}^{-1}=(B^{⊺}(-A+i*w*E{)}^{-1}B{)}^{-1}}$

A plots of ${\displaystyle Resis(w)}$ can be found in Rspiral_skin.pdf and a plot of ${\displaystyle Induc(w)}$ in Lspiral_skin.pdf.

Origin

This benchmark is part of the Oberwolfach Benchmark Collection^[1]; No. 38891, see ^[2].

Data

The model is of order ${\displaystyle N=1434}$ and of the form:

${\displaystyle \begin{array}{rcl}E\dot{x}(t)& =& Ax(t)+Bu(t)\\ y(t)& =& B^{⊺}x(t)\end{array}}$

and can be downloaded as PeekInductor-dim1e3-spiral_inductor_peec.tar.gz (10.5 MB).

Short Matlab files to:

• plot ${\displaystyle Resis(w)}$ and ${\displaystyle Induc(w)}$,
• perform a PRIMA reduction of order 50,
• produce symmetrized standard state-space system: ${\displaystyle \dot{x}(t)=A_{symm}x(t)+B_{symm}u(t)}$, ${\displaystyle y(t)=B_{symm}^{⊺}x(t)}$, where ${\displaystyle A_{symm}}$ is symmetric.

can be found in PeekInductor-plot_spiral.tar.gz

Dimensions

System structure:

${\displaystyle \begin{array}{rl}E\dot{x}(t)& =Ax(t)+Bu(t)\\ y(t)& =B^{⊺}x(t)\end{array}}$

System dimensions:

${\displaystyle E\in {\mathbb{ℝ}}^{1434\times 1434}}$, ${\displaystyle A\in {\mathbb{ℝ}}^{1434\times 1434}}$, ${\displaystyle B\in {\mathbb{ℝ}}^{1434\times 1}}$.

References