Difference between revisions of "File:Logi1a345T300.png"

Explicit plots of various iterations of the Logistic operator with various values of parameter $s$.

$y=\mathrm{LogisticOperator}_s^{\,c}(x)$ for $s\!=\!3$ (left), $s\!=\!4$ (center), $s\!=\!5$ (right) at $c=1$ (black), $c=0.8$ (blue), $c=0.5$ (green), $c=0.2$ (red).

The non-integer iterates of the logisticOperator are calculated through the functions LogisticSequence and ArcLogisticSequence with

$ \mathrm{LogisticPoerator}_s^{\,c}(z)= \mathrm{LogisticSequence}_s\Big( c + \mathrm{ArcLogisticSequence}(z) \big)$

C++ generator of curves for $s=3$

// FIels efjh.cin and ado.cin should be loaded to the working directory in order to compile the C++ code below.

#include <stdio.h>
#include <stdlib.h>
#define DB double
#define DO(x,y) for(x=0;x<y;x++)
using namespace std;
#include <complex>
typedef complex<double> z_type;
#define Re(x) x.real()
#define Im(x) x.imag()
#define I z_type(0.,1.)
#include "ado.cin"
#include "efjh.cin"

main(){ int j,k,m,n; DB x,y, p,q, t; z_type z,c,d;
FILE *o;o=fopen("logi1a3.eps","w");ado(o,104,104);
fprintf(o,"2 2 translate\n 100 100 scale\n");
#define M(x,y) fprintf(o,"%6.4f %6.4f M\n",0.+x,0.+y);
#define L(x,y) fprintf(o,"%6.4f %6.4f L\n",0.+x,0.+y);
M(0,0)L(1,0)L(1,1)L(0,1)
fprintf(o,"C .003 W 0 0 0 RGB S\n");
M(0,.25)L(1,.25) M(.25,0)L(.25,1)
M(0,.50)L(1,.50) M(.50,0)L(.50,1)
M(0,.75)L(1,.75) M(.75,0)L(.75,1)
fprintf(o,".003 W 0 0 0 RGB S\n");
fprintf(o,"1 setlinejoin 2 setlinecap\n");
maq(3.);
DO(m,101){x=1.-.0000999*m*m;y=Re(F(1.+E(x)));if(m==0)M(x,y)else L(x,y);}fprintf(o,".006 W 0 0 0 RGB S\n"); 
M(.75,9./16.) DO(m,101){x=.75-.0000749*m*m;y=Re(F(.8+E(x))); L(x,y);}fprintf(o,".006 W 0 0 .8 RGB S\n"); 
M(.75,9./16.) DO(m,101){x=.75-.0000749*m*m;y=Re(F(.5+E(x)));  L(x,y);}fprintf(o,".01 W 0 .8 0 RGB S\n"); 
M(.75,9./16.) DO(m,101){x=.75-.0000749*m*m;y=Re(F(.2+E(x)));  L(x,y);}fprintf(o,".006 W .8 0 0 RGB S\n"); 
fprintf(o,"showpage\n%c%cTrailer",'%','%'); fclose(o);
       system("epstopdf logi1a3.eps");
       system(    "open logi1a3.eps");
       getchar(); system("killall Preview");
}

C++ generator of curves for $s=4$

// FIels efjh.cin and ado.cin should be loaded to the working directory in order to compile the C++ code below.

#include <math.h>
#include <stdio.h>
#include <stdlib.h>
#define DB double
#define DO(x,y) for(x=0;x<y;x++)
using namespace std;
#include <complex>
typedef complex<double> z_type;
#define Re(x) x.real()
#define Im(x) x.imag()
#define I z_type(0.,1.)
#include "ado.cin"
#include "efjh.cin"

main(){ int j,k,m,n; DB x,y, p,q, t; z_type z,c,d;
FILE *o;o=fopen("logi1a4.eps","w");ado(o,104,104);
fprintf(o,"2 2 translate\n 100 100 scale\n");
#define M(x,y) fprintf(o,"%6.3f %6.3f M\n",0.+x,0.+y);
#define L(x,y) fprintf(o,"%6.3f %6.3f L\n",0.+x,0.+y);
M(0,0)L(1,0)L(1,1)L(0,1)
fprintf(o,"C .003 W 0 0 0 RGB S\n");
M(0,.25)L(1,.25) M(.25,0)L(.25,1)
M(0,.50)L(1,.50) M(.50,0)L(.50,1)
M(0,.75)L(1,.75) M(.75,0)L(.75,1)
fprintf(o,".003 W 0 0 0 RGB S\n");
fprintf(o,"1 setlinejoin 2 setlinecap\n");
maq(4.);
DO(m,101){x=1.-.0000999*m*m;y=Re(F(1.+E(x)));if(m==0)M(x,y)else L(x,y);}fprintf(o,".006 W 0 0 0 RGB S\n"); 
M(1,0) DO(m,101){x=1.-.0000999*m*m;y=Re(F(.8+E(x))); L(x,y);}fprintf(o,".006 W 0 0 .8 RGB S\n"); 
M(1,0) DO(m,101){x=1.-.0000999*m*m;y=Re(F(.5+E(x)));  L(x,y);}fprintf(o,".01 W 0 .8 0 RGB S\n"); 
M(1,0) DO(m,101){x=1.-.0000999*m*m;y=Re(F(.2+E(x)));  L(x,y);}fprintf(o,".006 W .8 0 0 RGB S\n"); 
fprintf(o,"showpage\n%c%cTrailer",'%','%'); fclose(o);
       system("epstopdf logi1a4.eps");
       system(    "open logi1a4.pdf");
       getchar(); system("killall Preview");
}

C++ generator of curves for $s=5$

// FIels efjh.cin and ado.cin should be loaded to the working directory in order to compile the C++ code below.

#include <math.h>
#include <stdio.h>
#include <stdlib.h>
#define DB double
#define DO(x,y) for(x=0;x<y;x++)
using namespace std;
#include <complex>
typedef complex<double> z_type;
#define Re(x) x.real()
#define Im(x) x.imag()
#define I z_type(0.,1.)
#include "ado.cin"
#include "efjh.cin"

main(){ int j,k,m,n; DB x,y, p,q, t; z_type z,c,d;
FILE *o;o=fopen("logi1a5.eps","w");ado(o,140,140);
fprintf(o,"2 2 translate\n 100 100 scale\n");
#define M(x,y) fprintf(o,"%6.4f %6.4f M\n",0.+x,0.+y);
#define L(x,y) fprintf(o,"%6.4f %6.4f L\n",0.+x,0.+y);
M(0,0)L(1.25,0)L(1.25,1.25)L(0,1.25)
fprintf(o,"C .003 W 0 0 0 RGB S\n");
M(0,.25)L(1.25,.25) M(.25,0)L(.25,1.25)
M(0,.50)L(1.25,.50) M(.50,0)L(.50,1.25)
M(0,.75)L(1.25,.75) M(.75,0)L(.75,1.25)
M(0,1.0)L(1.25,1.0) M(1.0,0)L(1.0,1.25)
fprintf(o,".003 W 0 0 0 RGB S\n");
fprintf(o,"1 setlinejoin 2 setlinecap\n");
maq(5);
DB x0=1.25;
DO(m,101){x=1.001-.00010001*m*m;y=Re(F(1.+E(x)));if(m==0)M(x,y)else L(x,y);}fprintf(o,".006 W 0 0 0 RGB S\n"); 
DO(m,101){x=1.17-.000116*m*m;y=Re(F(.8+E(x)));if(m==0)M(x,y)else L(x,y);}fprintf(o,".006 W 0 0 .8 RGB S\n"); 
M(1.25,-.02)
DO(m,101){x=x0-.0001249*m*m;y=Re(F(.5+E(x))); L(x,y);}fprintf(o,".01 W 0 .8 0 RGB S\n"); 
M(1.25,-.01)
DO(m,101){x=x0-.0001249*m*m;y=Re(F(.2+E(x))); L(x,y);}fprintf(o,".006 W .8 0 0 RGB S\n"); 
fprintf(o,"showpage\n%c%cTrailer",'%','%'); fclose(o);
       system("epstopdf logi1a5.eps");
       system(    "open logi1a5.pdf");
       getchar(); system("killall Preview");
}

Latex generator of labels

% Files logi1a3.pdf,logi1a4.pdf,logi1a5.pdf should be generated with the codes above in order to compile the Latex document below.

% %<br> \documentclass[12pt]{article} %<br> \usepackage{geometry} %<br> \usepackage{graphics} %<br> \usepackage{rotating} %<br> \paperwidth 394pt %<br> \paperheight 136pt %<br> \topmargin -100pt %<br> \oddsidemargin -75pt %<br> \newcommand \sx {\scalebox} %<br> \newcommand \ing \includegraphics %<br> \newcommand \rot {\begin{rotate}} %<br> \newcommand \ero {\end{rotate}} %<br> \parindent 0pt %<br> \pagestyle{empty} %<br> \begin{document} %<br> \newcommand \fiax { %<br> \put(3,108){\sx{.9}{1}} %<br> %\put(-9, 84){\sx{.9}{0.25}} %<br> \put(3, 58){\sx{.9}{$\frac{1}{2}$}} %<br> %\put(-9, 34){\sx{.9}{0.25}} %<br> \put(3, 8){\sx{.9}{0}} %<br> \put( 8, 1){\sx{.9}{0}} %<br> \put( 55, 1){\sx{.9}{0.5}} %<br> \put(108, 1){\sx{.9}{1}} %<br> } %<br> \begin{picture}(126,124) %<br> \put(8,8){\ing{logi1a3}} \fiax \put(2,124){\sx{1}{$y\!=\!T^{c}(x)$}} %<br> \put(31,63){\rot{51}\sx{.85}{$c\!=1$}\ero} %<br> \put(33,53){\rot{49}\sx{.85}{$c\!=0.8$}\ero} %<br> \put(39,48){\rot{48}\sx{.85}{$c\!=0.5$}\ero} %<br> \put(44,40){\rot{46}\sx{.85}{$c\!=0.2$}\ero} %<br> \put(118, 1){\sx{.9}{$x$}} %<br> \put(44,20){\sx{1.6}{$s\!=\!3$}} %<br> \end{picture} %<br> \begin{picture}(126,124) \put(8,8){\ing{logi1a4}} \fiax \put(2,124){\sx{1}{$y\!=\!T^{c}(x)$}} %<br> \put(32,84){\rot{57}\sx{.9}{$c\!=1$}\ero} %<br> \put(39,70){\rot{54}\sx{.88}{$c\!=0.8$}\ero} %<br> \put(46,65){\rot{51}\sx{.88}{$c\!=0.5$}\ero} %<br> \put(54,54){\rot{49}\sx{.9}{$c\!=0.2$}\ero} %<br> \put(118, 1){\sx{.9}{$x$}} %<br> \put(44,20){\sx{1.6}{$s\!=\!4$}} %<br> \end{picture} %<br> \begin{picture}(140,127) \put(8,8){\ing{logi1a5}} \fiax %\put(0,124){\sx{1}{$y$}} %<br> \put(34,107){\rot{61}\sx{.93}{$c\!=1$}\ero} %<br> \put(45, 90){\rot{59}\sx{.92}{$c\!=0.8$}\ero} %<br> \put(53, 77){\rot{55}\sx{.92}{$c\!=0.5$}\ero} %<br> \put(58, 60){\rot{50}\sx{.92}{$c\!=0.2$}\ero} %<br> \put(128, 1){\sx{.9}{$x$}} %<br> \put(44,20){\sx{1.6}{$s\!=\!5$}} %<br> \end{picture} %<br> \end{document} %<br> %%