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Description: Spiral Inductor PEEC Model

Figure 1: Spiral inductor with part of overhanging copper plane

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

The complex impedance is:

Z (w) = R e s i s (w) + i * w * I n d u c (w) = G (i * w)^{- 1} = (B^{⊺} (- A + i * w * E)^{- 1} B)^{- 1}

A plots of $R e s i s (w)$ can be found in Rspiral_skin.pdf and a plot of $I n d u c (w)$ 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 $N = 1434$ and of the form:

\begin{array}{rcl} E \dot{x} (t) & = & A x (t) + B u (t) \\ y (t) & = & B^{⊺} x (t) \end{array}

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

Short Matlab files to:

plot $R e s i s (w)$ and $I n d u c (w)$ ,
perform a PRIMA reduction of order 50,
produce symmetrized standard state-space system: $\dot{x} (t) = A_{s y m m} x (t) + B_{s y m m} u (t)$ , $y (t) = B_{s y m m}^{⊺} x (t)$ , where $A_{s y m m}$ is symmetric.

can be found in plot_spiral.tar.gz

Dimensions

System structure:

\begin{aligned} E \dot{x} (t) & = A x (t) + B u (t) \\ y (t) & = B^{⊺} x (t) \end{aligned}

System dimensions:

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

References

↑ J.G. Korvink, E.B. Rudnyi, Oberwolfach Benchmark Collection, Dimension Reduction of Large-Scale Systems, Lecture Notes in Computational Science and Engineering, vol 45: 311--315, 2005.
↑ J.R. Li, M. Kamon, Model of a Spiral Inductor Generated by Fasthenry. In: Dimension Reduction of Large-Scale Systems. Lecture Notes in Computational Science and Engineering, vol 45: 373--377, 2005.

[korvink2005-1] J.G. Korvink, E.B. Rudnyi, Oberwolfach Benchmark Collection, Dimension Reduction of Large-Scale Systems, Lecture Notes in Computational Science and Engineering, vol 45: 311--315, 2005.

[li2005-2] J.R. Li, M. Kamon, Model of a Spiral Inductor Generated by Fasthenry. In: Dimension Reduction of Large-Scale Systems. Lecture Notes in Computational Science and Engineering, vol 45: 373--377, 2005.

[1]

[2]

@@ Line 22: / Line 22: @@
 ==Origin==
-This benchmark is part of the '''Oberwolfach Benchmark Collection'''<ref name="korvink2005"/>; No. 38891.
+This benchmark is part of the '''Oberwolfach Benchmark Collection'''<ref name="korvink2005"/>; No. 38891, see <ref name="li2005"/>.
 ==Data==
@@ Line 39: / Line 39: @@
 * plot <math>Resis(w)</math> and <math>Induc(w)</math>,
-* perform a PRIMA reduction of order 50,
+* perform a [[PRIMA]] reduction of order 50,
 * produce symmetrized standard state-space system: <math>\dot{x}(t) = A_{symm}x(t)+ B_{symm}u(t)</math>, <math>y(t) = B_{symm}^\intercal x(t)</math>, where <math>A_{symm}</math> is symmetric.
 can be found in [https://portal.uni-freiburg.de/imteksimulation/downloads/benchmark/Peek%20inductor%20%2838891%29/files/fileinnercontentproxy.2010-02-08.4591806366 plot_spiral.tar.gz]
+==Dimensions==
+System structure:
+:<math>
+\begin{align}
+E \dot{x}(t) &= Ax(t) + Bu(t) \\
+y(t) &= B^\intercal x(t)
+\end{align}
+</math>
+System dimensions:
+<math>E \in \mathbb{R}^{1434 \times 1434}</math>,
+<math>A \in \mathbb{R}^{1434 \times 1434}</math>,
+<math>B \in \mathbb{R}^{1434 \times 1}</math>.
 ==References==
@@ Line 49: / Line 66: @@
 <ref name="korvink2005"> J.G. Korvink, E.B. Rudnyi, <span class="plainlinks">[https://doi.org/10.1007/3-540-27909-1_11 Oberwolfach Benchmark Collection]</span>, Dimension Reduction of Large-Scale Systems, Lecture Notes in Computational Science and Engineering, vol 45: 311--315, 2005.</ref>
+<ref name="li2005">J.R. Li, M. Kamon, <span class="plainlinks">[https://doi.org/10.1007/3-540-27909-1_23PEEC Model of a Spiral Inductor Generated by Fasthenry]</span>. In: Dimension Reduction of Large-Scale Systems. Lecture Notes in Computational Science and Engineering, vol 45: 373--377, 2005.</ref>
 </references>