Difference between revisions of "Nonlinear RC Ladder"

Revision as of 10:17, 29 March 2018

Description

Nonlinear RC-Ladder

The nonlinear RC-ladder is an electronic test circuit introduced in ^[1]. This nonlinear first-order system models a resistor-capacitor network that exhibits a distinct nonlinear behavior caused by the nonlinear resistors consisting of a parallel connected resistor with a diode.

Model

The underlying model is given by a (SISO) gradient system of the form ^[2]:

\dot{x}(t) = \begin{pmatrix} -g(x_1(t)) - g(x_1(t) - x_2(t)) \\ g(x_1(t)-x_2(t)) - g(x_2(t)-x_3(t)) \\ \vdots \\ g(x_{k-1}(t) - x_k(t)) - g(x_k(t) - x_{x+1}(t)) \\ \vdots \\ g(x_{N-1}(t) - x_N(t)) \end{pmatrix}+\begin{pmatrix}u(t) \\ 0 \\ \vdots \\ 0 \\ \vdots \\ 0 \end{pmatrix},

y(t) = x_1(t),

where the $g$ is a mapping $g(x_i):\mathbb{R} \to \mathbb{R}$ :

g(x_i) = g_D(x_i) + x_i,

which combines the effect of a diode and a resistor.

Nonlinearity

The nonlinearity $g_D$ models a diode as a nonlinear resistor, based on the Shockley model ^[3]:

g_D(x_i) = i_S (\exp(u_P x_i) - 1),

with material parameters $i_S > 0$ and $u_P > 0$ .

For this benchmark the parameters are selected as: $i_S = 1$ and $u_P = 40$ as in ^[1].

Input

As an external input, several alternatives are presented in ^[4], which are listed next. A simple step function is given by:

u_1(t)=\begin{cases}0 & t < 4 \\ 1 & t \geq 4 \end{cases},

an exponential decaying input is provided by:

u_2(t) = e^{-t}.

Additional input sources are given by conjunction of sine waves with different periods ^[5]:

u_3(t) = \sin(2\pi 50t)+\sin(2\pi 1000t),

u_4(t) = \sin(2\pi 50t) \sin(2\pi 1000t).

Data

A sample procedural MATLAB implementation of order $N$ is given by:

function [f,B,C] = nrc(N)
%% Procedural generation of "Nonlinear RC Ladder" benchmark system

  % nonlinearity
  g = @(x) exp(40.0*x) + x - 1.0;

  A0 = sparse(N,N);
  A0(1,1) = 1;

  A1 = spdiags(ones(N-1,1),-1,N,N) - speye(N);
  A1(1,1) = 0;

  A2 = spdiags([ones(N-1,1);0],0,N,N) - spdiags(ones(N,1),1,N,N);

  % input matrix
  B = sparse(N,1);
  B(1,1) = 1;

  % output matrix
  C = sparse(1,N);
  C(1,1) = 1;

  % vector field and output functional
  f = @(x) -g(A0*x) + g(A1*x) - g(A2*x);

end

Here the nonlinear part of the vectorfield is realized in a vectorized form as a closure.

Dimensions

System structure:

\begin{align} \dot{x}(t) &= f(x(t)) + Bu(t), \\ y(t) &= Cx(t). \end{align}

System dimensions:

$f : \mathbb{R}^N \to \mathbb{R}^N$ , $B \in \mathbb{R}^{N \times 1}$ , $C \in \mathbb{R}^{1 \times N}$ .

Citation

To cite this benchmark, use the following references:

For the benchmark itself and its data:

The MORwiki Community. Nonlinear RC Ladder. MORwiki - Model Order Reduction Wiki, 2018. http://modelreduction.org/index.php/Nonlinear_RC_Ladder

   @MISC{morwiki_modNonRCL,
    author = {The {MORwiki} Community},
    title = {Nonlinear RC Ladder},
    howpublished = {{MORwiki} -- Model Order Reduction Wiki},
    url = {http://modelreduction.org/index.php/Nonlinear_RC_Ladder},
    year = {2018}
   }

For the background on the benchmark: morChe99 (BibTeX)

References

↑ ^1.0 ^1.1 Y. Chen, "Model Reduction for Nonlinear Systems", Master Thesis, 1999.
↑ M. Condon and R. Ivanov, "Empirical balanced truncation for nonlinear systems", Journal of Nonlinear Science 14(5):405--414, 2004.
↑ T. Reis. "Mathematical Modeling and Analysis of Nonlinear Time-Invariant RLC Circuits", In: Large-Scale Networks in Engineering and Life Sciences. Modeling and Simulation in Science, Engineering and Technology: 125--198, 2014.
↑ Y. Chen and J. White, "A quadratic method for nonlinear model order reduction", Int. Conference on Modelling and Simulation of Microsystems Semiconductors, Sensors and Actuators, 2000.
↑ M. Condon and R. Ivanov, "Model Reduction of Nonlinear Systems", COMPEL 23(2): 547--557, 2004

Contact

Christian Himpe

[chen99-1] 1.0 ^1.1 Y. Chen, "Model Reduction for Nonlinear Systems", Master Thesis, 1999.

[condon04-2] M. Condon and R. Ivanov, "Empirical balanced truncation for nonlinear systems", Journal of Nonlinear Science 14(5):405--414, 2004.

[reis14-3] T. Reis. "Mathematical Modeling and Analysis of Nonlinear Time-Invariant RLC Circuits", In: Large-Scale Networks in Engineering and Life Sciences. Modeling and Simulation in Science, Engineering and Technology: 125--198, 2014.

[chen00-4] Y. Chen and J. White, "A quadratic method for nonlinear model order reduction", Int. Conference on Modelling and Simulation of Microsystems Semiconductors, Sensors and Actuators, 2000.

[condon04a-5] M. Condon and R. Ivanov, "Model Reduction of Nonlinear Systems", COMPEL 23(2): 547--557, 2004

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@@ Line 142: / Line 142: @@
 <ref name="chen99">Y. Chen, "<span class="plainlinks">[http://hdl.handle.net/1721.1/9381 Model Reduction for Nonlinear Systems]</span>", Master Thesis, 1999.</ref>
-<ref name="chen00">Y. Chen and J. White, "<span class="plainlinks">[http://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.19.8951&rep=rep1&type=pdf A quadratic method for nonlinear model order reduction]</span>", Int. conference on modelling and simulation of Microsystems semiconductors, sensors and actuators, 2000.</ref>
+<ref name="chen00">Y. Chen and J. White, "<span class="plainlinks">[http://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.19.8951&rep=rep1&type=pdf A quadratic method for nonlinear model order reduction]</span>", Int. Conference on Modelling and Simulation of Microsystems Semiconductors, Sensors and Actuators, 2000.</ref>
 <ref name="condon04">M. Condon and R. Ivanov, "<span class="plainlinks">[https://doi.org/10.1007/s00332-004-0617-5 Empirical balanced truncation for nonlinear systems]</span>", Journal of Nonlinear Science 14(5):405--414, 2004.</ref>