Control package

The control package is part of the Octave Forge project.

Function list

Linear System Representation

Model Interconnection

Model Transformation

Linear Analysis

Control Design

Matrix Computations

Examples

PT1 / Low-pass filter step response

 T1 = 0.4;              # time constant
 P = tf([1], [T1 1]);   # create transfer function model
 step(P, 2)             # plot step response

 #add some common markers like the tangent line at the origin, which crosses lim(n->inf) f(t) at t=T1
 hold on
 plot ([0 T1], [0 1], "g")
 plot ([T1 T1], [0 1], "k")
 plot ([0 T1], [1-1/e 1-1/e], "m")
 hold off

Bode Diagram for TikZ/PGFplots

We use the same system as before but we draw now with bode(P) a bode diagram. The output is written to a .csv file.

T1 = 0.4;              # time constant
P = tf([1], [T1 1]);

[mag, pha, w] = bode(P);

csvwrite("dat/bode_p.csv", [w', 20*log10(mag), pha]);

We can then invoke LaTeX with the following .tex file

\documentclass[tikz]{standalone}
\usepackage{pgfplotstable}
\usepackage{siunitx}
\usetikzlibrary{pgfplots.groupplots}

\begin{document}
\pgfplotstableread[col sep=comma]{\detokenize{/path/to/csv/file/dat/bode_p.csv}}\datatable
\begin{tikzpicture}
\begin{groupplot}[
  group style={rows=2}, 
  width=0.8\textwidth,
  height=0.4\textwidth, 
  xmajorgrids, 
  ymajorgrids, 
  enlarge x limits=false,
] 
  \nextgroupplot[
    title={Bode Diagram of $P$},
    xmode=log,
    ylabel={Magnitude / \si{\decibel}},
  ]
  \addplot[blue,line width=1pt] table[x index=0,y index=1]{\datatable}; 
  \nextgroupplot[
    xmode=log,
    xlabel={Frequency / \si{\radian\per\second}},
    ylabel={Phase / \si{\degree}},
  ] 
  \addplot[red,line width=1pt] table[x index=0,y index=2]{\datatable};
\end{groupplot}
\end{tikzpicture}
\end{document}

to generate a beautiful bode diagram

It can be seen that a first order low-pass filter has ${\textstyle -3\,dB}$ magnitude at ${\textstyle f=1/T_{1}=2.5\,Hz}$.

Inverted Pendulum

A nonlinear model of the inverted pendulum can be derived by

${\displaystyle {\begin{cases}(M+m){\ddot {x}}+c{\dot {x}}-ml\cos {\theta }{\ddot {\theta }}+ml\sin {\theta }{\dot {\theta }}^{2}&=f(t)\\-ml{\ddot {x}}\cos {\theta }+(ml^{2}+I){\ddot {\theta }}+b{\dot {\theta }}+mgl\sin {\theta }&=0\end{cases}}{\text{,}}}$

where the variables are defined as

Name	Definition
${\textstyle M}$	Mass of the cart
${\textstyle m}$	Mass of the pendulum
${\textstyle c}$	Translational damping coefficient
${\textstyle l}$	Length of the pendulum
${\textstyle I}$	Inertia of the pendulum
${\textstyle b}$	Rotational damping coefficient

Linearization around the point ${\textstyle \theta =\pi }$ and substitution of ${\textstyle \theta '=\theta -\pi }$ (from here on in the analysis, ${\textstyle \theta '}$ will be written as ${\textstyle \theta }$, but it should be noted that ${\textstyle \theta }$ now measures from a new reference) leads to

${\displaystyle {\begin{cases}(M+m){\ddot {x}}+c{\dot {x}}+ml{\ddot {\theta }}&=f(t)\\ml{\dot {x}}+(ml^{2}+I){\ddot {\theta }}+b{\dot {\theta }}-mgl\theta &=0\end{cases}}{\text{.}}}$

This can be expressed in the frequency domain like

${\displaystyle {\begin{cases}(M+m)s^{2}X(s)+csX(s)+mls^{2}\Theta (s)&=F(s)\\mlsX(s)+(ml^{2}+I)s^{2}\Theta (s)+bs\Theta (s)-mgl\Theta (s)&=0\end{cases}}}$

and by dividing the state variables by the input one obtains the transfer functions

${\displaystyle {\begin{aligned}G_{1}(s)&={\frac {X(s)}{F(s)}}={\frac {\alpha _{2}s^{2}+\alpha _{1}s+\alpha _{0}}{\beta _{4}s^{4}+\beta _{3}s^{3}+\beta _{2}s^{2}+\beta _{1}s}}\\G_{2}(s)&={\frac {\Theta (s)}{F(s)}}={\frac {\gamma _{1}s}{\beta _{4}s^{3}+\beta _{3}s^{2}+\beta _{2}s+\beta _{1}}}\end{aligned}}}$

with

${\textstyle \alpha _{2}=ml^{2}+I}$

${\textstyle \alpha _{1}=b}$

${\textstyle \alpha _{0}=-mgl}$

${\textstyle \beta _{4}=(M+m)(ml^{2}+I)-m^{2}l^{2}}$

${\textstyle \beta _{3}=(M+m)b+(ml^{2}+I)c}$

${\textstyle \beta _{2}=-(M+m)mgl+bc}$

${\textstyle \beta _{1}=-mglc}$

${\textstyle \gamma _{1}=-ml}$

This can be expressed in Octave

 m = 0.15;
 l = 0.314;
 M = 1.3;
 I = 7.38e-5;
 g = 9.80665;
 b = 20;
 c = 0;
 G1 = tf([m*l^2+I b -m*g*l],
         [(M+m)*(m*l^2+I)-m^2*l^2 (M+m)*b+(m*l^2+I)*c -(M+m)*m*g*l+b*c -m*g*l*c 0]);
 G2 = tf([-m*l],
         [(M+m)*(m*l^2+I)-m^2*l^2 (M+m)*b+(m*l^2+I)*c -(M+m)*m*g*l+b*c -m*g*l*c]);

and by invoking the bode command

 bode(G1);
 bode(G2);

one obtains the Bode plots of the two transfer functions.

References