File:Exp09mapT200.jpg
Original file (2,281 × 1,179 pixels, file size: 1.23 MB, MIME type: image/jpeg)
Compex map of the $0.9$th iteration of exponent,
$u+\mathrm i v= \exp^{0.9}(x+\mathrm i y)= \mathrm{tet}(0.9+\mathrm{ate}(x+\mathrm i y)$
For the evaluation, the non-integer iterate of exponential is expressed through tetration tet and arctetration ate. The complex double implementations FSEXP and FSLOG are used in the C++ code below.
C++ generator of curves
// Files ado.fin, conto.cin, fsexp.cin and fslog.cin should be loaded in the working directory in order to compile the 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 "conto.cin" #include "fsexp.cin" #include "fslog.cin" main(){ int j,k,m,n; DB x,y, p,q, t; z_type z,c,d, cu,cd; int M=401,M1=M+1; int N=403,N1=N+1; DB X[M1],Y[N1]; DB *g, *f, *w; // w is working array. g=(DB *)malloc((size_t)((M1*N1)*sizeof(DB))); f=(DB *)malloc((size_t)((M1*N1)*sizeof(DB))); w=(DB *)malloc((size_t)((M1*N1)*sizeof(DB))); char v[M1*N1]; // v is working array FILE *o;o=fopen("exp09map.eps","w"); ado(o,802,402); fprintf(o,"401 1 translate\n 100 100 scale\n"); fprintf(o,"1 setlinejoin 2 setlinecap\n"); DO(m,M1) X[m]=-4+.02*(m-.5); DO(n,N1) { y=0.+.01*(n-.5); if(y>Im(Zo)) break; Y[n]=y; } Y[n] =Im(Zo)-.00001; Y[n+1]=Im(Zo)+.00001; for(m=n+2;m<N1;m++) Y[m]=.01*(m-2-.5); for(m=-4;m<5;m++){M(m,0) L(m,4) } for(n=0;n<5;n++){M( -4,n) L(4,n)} fprintf(o,".006 W 0 0 0 RGB S\n"); DO(m,M1)DO(n,N1){ g[m*N1+n]=999; f[m*N1+n]=999;} DO(m,M1){x=X[m]; if(m/10*10==m) printf("x=%6.3f\n",x); DO(n,N1){y=Y[n]; z=z_type(x,y); //if(abs(z+2.)>.019) c=FSEXP(.9+FSLOG(z)); p=Re(c); q=Im(c);// if(p>-19 && p<19 && ( x<2. || fabs(q)>1.e-12 && fabs(p)>1.e-12) ) { g[m*N1+n]=p;f[m*N1+n]=q;} }} fprintf(o,"1 setlinejoin 1 setlinecap\n"); p=2.;q=1; conto(o,g,w,v,X,Y,M,N, Re(Zo),-p,p);fprintf(o,".03 W 0 1 0 RGB S\n"); conto(o,f,w,v,X,Y,M,N, Im(Zo),-p,p);fprintf(o,".03 W 0 1 0 RGB S\n"); for(m=-8;m<8;m++)for(n=2;n<10;n+=2)conto(o,f,w,v,X,Y,M,N,(m+.1*n),-q,q);fprintf(o,".007 W 0 .6 0 RGB S\n"); for(m=0;m<8;m++) for(n=2;n<10;n+=2)conto(o,g,w,v,X,Y,M,N,-(m+.1*n),-q,q);fprintf(o,".007 W .9 0 0 RGB S\n"); for(m=0;m<8;m++) for(n=2;n<10;n+=2)conto(o,g,w,v,X,Y,M,N, (m+.1*n),-q,q);fprintf(o,".007 W 0 0 .9 RGB S\n"); for(m= 1;m<17;m++) conto(o,f,w,v,X,Y,M,N, (0.-m),-q,q);fprintf(o,".02 W .8 0 0 RGB S\n"); for(m= 1;m<17;m++) conto(o,f,w,v,X,Y,M,N, (0.+m),-q,q);fprintf(o,".02 W 0 0 .8 RGB S\n"); conto(o,f,w,v,X,Y,M,N, (0. ),-p,p); fprintf(o,".02 W .5 0 .5 RGB S\n"); for(m=-16;m<17;m++)conto(o,g,w,v,X,Y,M,N,(0.+m),-q,q);fprintf(o,".02 W 0 0 0 RGB S\n"); fprintf(o,"0 setlinejoin 0 setlinecap\n");
M(Re(Zo),Im(Zo))L(-4,Im(Zo)) fprintf(o,"1 1 1 RGB .022 W S\n"); DO(n,40){M(Re(Zo)-.2*n,Im(Zo))L(Re(Zo)-.2*(n+.4),Im(Zo)) } fprintf(o,"0 0 0 RGB .032 W S\n"); fprintf(o,"showpage\n"); fprintf(o,"%c%cTrailer\n",'%','%'); fclose(o); free(f); free(g); free(w); system("epstopdf exp09map.eps"); system( "open exp09map.pdf"); //for macintosh getchar(); system("killall Preview"); // For macintosh }
Latex generator of labels
% File exp09map.pdf should be generated with the C++ code above in order to compile the Latex document below.
\documentclass[12pt]{article}
\usepackage{geometry}
\paperwidth 824pt
\paperheight 426pt
\usepackage{graphics}
\usepackage{rotating}
\newcommand \rot {\begin{rotate} }
\newcommand \ero {\end{rotate} }
\textwidth 810pt
\topmargin -105pt
\oddsidemargin -72pt
\pagestyle{empty}
\parindent 0pt
\newcommand \sx {\scalebox}
\begin{document}
\begin{picture}(820,420)
\put(20,20){\includegraphics{exp09map}}
\put(4,412){\sx{2.2}{$y$}}
\put(4,313){\sx{2.2}{$3$}}
\put(4,213){\sx{2.2}{$2$}}
\put(4,113){\sx{2.2}{$1$}}
\put(4,16){\sx{2.2}{$0$}}
\put(2,0){\sx{2.2}{$-4$}}
\put(100,0){\sx{2.2}{$-3$}}
\put(200,0){\sx{2.2}{$-2$}}
\put(300,0){\sx{2.2}{$-1$}}
\put(420,0){\sx{2.2}{$0$}}
\put(520,0){\sx{2.2}{$1$}}
\put(620,0){\sx{2.2}{$2$}}
\put(720,0){\sx{2.2}{$3$}}
\put(810,0){\sx{2.2}{$x$}}
%\put(140,329){\sx{2.4}{$v\!=\!0$}}
\put(200,300){\sx{2}{\rot{-55} $u\!=\!-0.2$ \ero}}
\put(273,307){\sx{2}{\rot{-50} $u\!=\!-0.4$ \ero}}
\put(323,318){\sx{2}{\rot{-56} $u\!=\!-0.6$ \ero}}
\put(353,330){\sx{2}{\rot{-60} $u\!=\!-0.8$ \ero}}
%
\put(264,188){\sx{2}{\rot{ 64} $v\!=\!0.2$ \ero}}
\put(327,173){\sx{2}{\rot{ 73} $v\!=\!0.4$ \ero}}
\put(369,174){\sx{2}{\rot{ 79} $v\!=\!0.6$ \ero}}
\put(398,177){\sx{2}{\rot{ 79} $v\!=\!0.8$ \ero}}
\put(422,180){\sx{2.2}{\rot{ 82} $v\!=\!1$ \ero}}
\put(450,178){\sx{1.9}{\rot{ 79} $v\!=\!\Im(L)$ \ero}}
\put(495,178){\sx{2}{\rot{ 90} $v\!=\!2$ \ero}}
\put(539,178){\sx{2}{\rot{ 90} $v\!=\!3$ \ero}}
\put(570,178){\sx{2}{\rot{ 90} $v\!=\!4$ \ero}}
%\put(40,180){\sx{2}{$u=0$}}
\put(62,226){\sx{2.4}{\rot{22}$v\!=\!0$\ero}}
%
\put(204,38){\sx{2.4}{\rot{ 66} $u\!=\!0$ \ero}}
\put(303,22){\sx{2}{\rot{ 70} $u\!=\!0.2$ \ero}}
\put(332,22){\sx{2}{\rot{ 69} $u\!=\!\Re(L)$ \ero}}
\put(356,22){\sx{2}{\rot{ 70} $u\!=\!0.4$ \ero}}
\put(386,22){\sx{2}{\rot{ 70} $u\!=\!0.6$ \ero}}
\put(412,22){\sx{2}{\rot{ 70} $u\!=\!0.8$ \ero}}
\put(435,22){\sx{2.2}{\rot{ 70} $u\!=\!1$ \ero}}
\put(506,22){\sx{2.2}{\rot{ 73} $u\!=\!2$ \ero}}
\put(546,22){\sx{2.2}{\rot{ 73} $u\!=\!3$ \ero}}
\put(580,22){\sx{2.2}{\rot{ 73} $u\!=\!4$ \ero}}
\put(56,150){\sx{2.6}{\bf cut}}
\end{picture}
\end{document}
References
http://www.ams.org/journals/bull/1993-29-02/S0273-0979-1993-00432-4/S0273-0979-1993-00432-4.pdf Walter Bergweiler. Iteration of meromorphic functions. Bull. Amer. Math. Soc. 29 (1993), 151-188.
http://www.ams.org/mcom/2009-78-267/S0025-5718-09-02188-7/home.html http://www.ils.uec.ac.jp/~dima/PAPERS/2009analuxpRepri.pdf http://mizugadro.mydns.jp/PAPERS/2009analuxpRepri.pdf D. Kouznetsov. Solution of F(x+1)=exp(F(x)) in complex z-plane. 78, (2009), 1647-1670
http://www.ils.uec.ac.jp.jp/~dima/PAPERS/2009vladie.pdf (English) http://mizugadro.mydns.jp/PAPERS/2010vladie.pdf (English) http://mizugadro.mydns.jp/PAPERS/2009vladir.pdf (Russian version) D.Kouznetsov. Superexponential as special function. Vladikavkaz Mathematical Journal, 2010, v.12, issue 2, p.31-45.
http://reference.wolfram.com/mathematica/ref/Nest.html Nest, Wolfram Mathematica 9 Documentation center, 2013
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current | 01:18, 27 July 2013 | 2,281 × 1,179 (1.23 MB) | T (talk | contribs) | Compex map of the $0.9$th iteration of exponent, $u+\mathrm i v= \exp^{0.9}(x+\mathrm i y)= \mathrm{tet}(0.9+\mathrm{ate}(x+\mathrm i y)$ For the evaluation, the non-integer iterate of exponential is expressed through tetration tet and [... |
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