File:Geometrically finite Julia set.png
Size of this preview: 780 × 600 pixels. Other resolutions: 312 × 240 pixels | 624 × 480 pixels | 999 × 768 pixels | 1,280 × 985 pixels | 2,600 × 2,000 pixels.
Original file (2,600 × 2,000 pixels, file size: 165 KB, MIME type: image/png)
 | This is a file from the Wikimedia Commons. Information from its description page there is shown below. Commons is a freely licensed media file repository. You can help. |
Summary
| Description |
English: Geometrically finite Julia set for the family of polynomials F(z,C):=z(1+z)(1+z)(C-(2C+1)z+(3+4C)zz/4). Here parameter C = 1.02+0.05i. "A rational map is called geometrically finite if every critical point in the Julia set is eventually periodic". Map and description by Tomoki Kawahira[1] |
| Date | |
| Source | Own work |
| Author | Adam majewski |
| Other versions |
|
c source code
/*
Adam Majewski
adammaj1 aaattt o2 dot pl // o like oxygen not 0 like zero
Structure of a program or how to analyze the program
============== Image X ========================
DrawImageOfX -> DrawPointOfX -> ComputeColorOfX
first 2 functions are identical for every X
check only last function = ComputeColorOfX
which computes color of one pixel !
==========================================
---------------------------------
indent d.c
default is gnu style
-------------------
c console progam
export OMP_DISPLAY_ENV="TRUE"
gcc d.c -lm -Wall -march=native -fopenmp
time ./a.out > b.txt
gcc d.c -lm -Wall -march=native -fopenmp
time ./a.out
time ./a.out >i.txt
time ./a.out >e.txt
convert -limit memory 1000mb -limit disk 1gb dd30010000_20_3_0.90.pgm -resize 2000x2000 10.png
*/
#include <stdio.h>
#include <stdlib.h> // malloc
#include <string.h> // strcat
#include <math.h> // M_PI; needs -lm also
#include <complex.h>
#include <omp.h> // OpenMP
#include <limits.h> // Maximum value for an unsigned long long int
// https://sourceforge.net/p/predef/wiki/Standards/
#if defined(__STDC__)
#define PREDEF_STANDARD_C_1989
#if defined(__STDC_VERSION__)
#if (__STDC_VERSION__ >= 199409L)
#define PREDEF_STANDARD_C_1994
#endif
#if (__STDC_VERSION__ >= 199901L)
#define PREDEF_STANDARD_C_1999
#endif
#endif
#endif
/* --------------------------------- global variables and consts ------------------------------------------------------------ */
// virtual 2D array and integer ( screen) coordinate
// Indexes of array starts from 0 not 1
//unsigned int ix, iy; // var
static unsigned int ixMin = 0; // Indexes of array starts from 0 not 1
static unsigned int ixMax; //
static unsigned int iWidth; // horizontal dimension of array
static unsigned int iyMin = 0; // Indexes of array starts from 0 not 1
static unsigned int iyMax; //
static unsigned int iHeight = 10000; //
// The size of array has to be a positive constant integer
static unsigned long long int iSize; // = iWidth*iHeight;
// memmory 1D array
unsigned char *data;
unsigned char *edge;
//unsigned char *edge2;
// unsigned int i; // var = index of 1D array
//static unsigned int iMin = 0; // Indexes of array starts from 0 not 1
static unsigned int iMax; // = i2Dsize-1 =
// The size of array has to be a positive constant integer
// unsigned int i1Dsize ; // = i2Dsize = (iMax -iMin + 1) = ; 1D array with the same size as 2D array
// see SetPlane
double radius = 1.2;
complex double center = 0.0;
double DisplayAspectRatio = 1.3; // https://en.wikipedia.org/wiki/Aspect_ratio_(image)
// dx = dy compare setup : iWidth = iHeight;
double ZxMin; //= -1.3; //-0.05;
double ZxMax;// = 1.3; //0.75;
double ZyMin;// = -1.3; //-0.1;
double ZyMax;// = 1.3; //0.7;
double PixelWidth; // =(ZxMax-ZxMin)/ixMax;
double PixelHeight; // =(ZyMax-ZyMin)/iyMax;
double ratio;
/*
ER = pow(10,ERe);
AR = pow(10,-ARe);
*/
//int ARe ; // increase ARe until black ( unknown) points disapear
//int ERe ;
double ER;
double ER2; //= 1e60;
double AR; // bigger values do not works
double AR2;
double AR12;
int IterMax = 100000;
/* colors = shades of gray from 0 to 255
unsigned char colorArray[2][2]={{255,231}, {123,99}};
color = 245; exterior
*/
unsigned char iColorOfExterior = 245;
unsigned char iColorOfInterior1 = 99;
unsigned char iColorOfInterior2 = 183;
unsigned char iColorOfBoundary = 0;
unsigned char iColorOfUnknown = 5;
// pixel counters
unsigned long long int uUnknown = 0;
unsigned long long int uInterior = 0;
unsigned long long int uExterior = 0;
// critical points
complex double zc1a = -0.47068779553447764874 + 0.0026098248687148155323*I; //period 1 attract
complex double zc1p = 0.24496023578261891251 + 0.0050657319837705428595*I; // period 1 attracting from parabolic
// periodic points = attractors
complex double zp1a =-0.33036439123272171026-0.035156244692189524137*I ; //period 1 attract
complex double zp1p = 0.024367377494104072722 +0.043208283893844831591*I ; // period 1 attracting from parabolic
/*
F(z,C):=z(1+z)(1+z)(C-(2C+1)z+(3+4C)zz/4)
Then for any C, F(z,C) has the following properties:
1. z=0 is a fixed point with multiplier C.
2. z=-1 is a critical point and F(-1,C)=0.
3. z=1 is another critical point, and F(1,C)=-1, thus F(F(1,C),C)=0
C*z^5+(3*z^5)/4+z^4/2-2*C*z^3-(5*z^3)/4-z^2+C*z
C*z^5
+(3*z^5)/4
+z^4/2
-2*C*z^3
-(5*z^3)/4
-z^2
+C*z
==============
(%o12) C*z^5+(3*z^5)/4+z^4/2-2*C*z^3-(5*z^3)/4-z^2+C*z
(%i13) coeff(f,z,5);
(%o13) C+3/4 = 0.058*%i+1.77
(%i14) coeff(f,z,4);
(%o14) 1/2
(%i15) coeff(f,z,3);
(%o15) (-2*C)-5/4 = (-0.116*%i)-3.29
(%i16) coeff(f,z,2);
(%o16) -1
(%i17) coeff(f,z,1);
(%o17) C = 1.02 + 0.05*I;
(%i18) coeff(f,z,0);
(%o18) 0
=============================
coefficients read from input file kawahira_sc_c3.txt
degree 5 coefficient = ( +1.7700000000000000 +0.0580000000000000*i)
degree 4 coefficient = ( +0.5000000000000000 +0.0000000000000000*i)
degree 3 coefficient = ( -3.2900000000000000 -0.1160000000000000*i)
degree 2 coefficient = ( -1.0000000000000000 +0.0000000000000000*i)
degree 1 coefficient = ( +1.0200000000000000 +0.0500000000000000*i)
degree 0 coefficient = ( +0.0000000000000000 +0.0000000000000000*i)
Input polynomial p(z)=(1.7700000000000000178+0.058000000000000002942i)*z^5+(0.5+0i)*z^4+(-3.2900000000000000355-0.11600000000000000588i)*z^3+(-1+0i)*z^2+(1.0200000000000000178+0.050000000000000002776i)*z^1
3 critical points found
cp#0: -0.47068779553447764874,0.0026098248687148155323 . It's critical orbit is bounded and enters cycle #0 length=1 and it's stability = |multiplier|=0.66225 =attractive
internal angle = 0.97054734997537162045
cycle = {
-0.33036439123272171026,-0.035156244692189524137 ; }
cp#1: 0.24496023578261891251,0.0050657319837705428595 . It's critical orbit is bounded and enters cycle #1 length=1 and it's stability = |multiplier|=0.98594 =attractive
internal angle = 0.99082387912800862217
cycle = {
0.024367377494104072722,0.043208283893844831591 ; }
cp#2: -1.0000287546513304537,-0.00068489313584920526092 . It's critical orbit is bounded and enters cycle #1
*/
// C=1.02+0.05i
complex double C = 1.02 + 0.05*I;
/* ------------------------------------------ functions -------------------------------------------------------------*/
//------------------complex numbers -----------------------------------------------------
// from screen to world coordinate ; linear mapping
// uses global cons
double
GiveZx (int ix)
{
return (ZxMin + ix * PixelWidth);
}
// uses globaal cons
double
GiveZy (int iy)
{
return (ZyMax - iy * PixelHeight);
} // reverse y axis
complex double
GiveZ (int ix, int iy)
{
double Zx = GiveZx (ix);
double Zy = GiveZy (iy);
return Zx + Zy * I;
}
double cabs2(complex double z){
return creal(z)*creal(z)+cimag(z)*cimag(z);
}
// =====================
int IsPointInsideTrap1(complex double z){
if ( cabs2(z - zp1a) < AR2) {return 1;} // circle with prabolic point zp on it's boundary
return 0; // outside
}
// =====================
int IsPointInsideTrap2(complex double z){
if (cabs2(z - zp1p) <AR2) {return 1;} // circle around periodic point
return 0; // outside
}
complex double F(complex double z, complex double C){
return (z*(1+z)*(1+z)*(C-(2*C+1)*z+(3+4*C)*z*z/4));
};
// ****************** DYNAMICS = trap tests ( target sets) ****************************
/* ----------- array functions = drawing -------------- */
/* gives position of 2D point (ix,iy) in 1D array ; uses also global variable iWidth */
unsigned int
Give_i (unsigned int ix, unsigned int iy)
{
return ix + iy * iWidth;
}
// f(z)=1+z−3z2−3.75z3+1.5z4+2.25z5
unsigned char
ComputeColor_Fatou (complex double z, int IterMax)
{
double r2;
int i; // number of iteration
for (i = 0; i < IterMax; ++i)
{
z = F(z,C); // complex iteration f(z)=z^6+A*z+c
r2 =cabs2(z);
if (r2 > ER2) // esaping = exterior
{
uExterior += 1;
return iColorOfExterior;
}
// solid color for each Fatou components
if ( IsPointInsideTrap1(z)) {
uInterior +=1;
return iColorOfInterior1;
} // 50 + (i % 114); }
if (IsPointInsideTrap2(z)){
uInterior +=1;
return iColorOfInterior2;}
}
uUnknown += 1;
return iColorOfUnknown;
}
// plots raster point (ix,iy)
int
DrawFatouPoint (unsigned char A[], int ix, int iy, int IterMax)
{
int i; /* index of 1D array */
unsigned char iColor = 0;
complex double z;
i = Give_i (ix, iy); /* compute index of 1D array from indices of 2D array */
z = GiveZ (ix, iy);
iColor = ComputeColor_Fatou (z, IterMax);
A[i] = iColor; // interior
return 0;
}
// fill array
// uses global var : ...
// scanning complex plane
int
DrawFatouImage (unsigned char A[], int IterMax)
{
unsigned int ix, iy; // pixel coordinate
fprintf (stdout, "compute Fatou image \n");
// for all pixels of image
#pragma omp parallel for schedule(dynamic) private(ix,iy) shared(A, ixMax , iyMax, uUnknown, uInterior, uExterior)
for (iy = iyMin; iy <= iyMax; ++iy)
{
fprintf (stderr, " %d from %d \r", iy, iyMax); //info
for (ix = ixMin; ix <= ixMax; ++ix)
DrawFatouPoint (A, ix, iy, IterMax); //
}
return 0;
}
//=========
int IsInside (int x, int y, int xcenter, int ycenter, int r){
double dx = x- xcenter;
double dy = y - ycenter;
double d = sqrt(dx*dx+dy*dy);
if (d<r)
return 1;
return 0;
}
int PlotBigPoint(complex double z, unsigned char A[]){
unsigned int ix_seed = (creal(z)-ZxMin)/PixelWidth;
unsigned int iy_seed = (ZyMax - cimag(z))/PixelHeight;
unsigned int i;
/* mark seed point by big pixel */
int iSide =1.0*iWidth/4000.0 ; /* half of width or height of big pixel */
int iY;
int iX;
for(iY=iy_seed-iSide;iY<=iy_seed+iSide;++iY){
for(iX=ix_seed-iSide;iX<=ix_seed+iSide;++iX){
if (IsInside(iX, iY, ix_seed, iy_seed, iSide)) {
i= Give_i(iX,iY); /* index of _data array */
A[i]= 255-A[i];}}}
return 0;
}
// fill array
// uses global var : ...
// scanning complex plane
int MarkAttractors (unsigned char A[])
{
fprintf (stderr, "mark attractors \n");
PlotBigPoint(zp1a, A); // period 114 cycle
PlotBigPoint(zp1p, A); // period 2 attracting cycle
return 0;
}
// =====================
int IsPointInsideTraps(unsigned int ix, unsigned int iy){
complex double z = GiveZ (ix, iy);
if ( IsPointInsideTrap1(z)) {return 1;} // circle with prabolic point on it's boundary
if (IsPointInsideTrap2(z)) {return 1;}
return 0; // outside
}
int MarkTraps(unsigned char A[]){
unsigned int ix, iy; // pixel coordinate
unsigned int i;
fprintf (stderr, "Mark traps \n");
// for all pixels of image
#pragma omp parallel for schedule(dynamic) private(ix,iy) shared(A, ixMax , iyMax, uUnknown, uInterior, uExterior)
for (iy = iyMin; iy <= iyMax; ++iy)
{
fprintf (stderr, " %d from %d \r", iy, iyMax); //info
for (ix = ixMin; ix <= ixMax; ++ix){
if (IsPointInsideTraps(ix, iy)) {
i= Give_i(ix,iy); /* index of _data array */
A[i]= 255-A[i]; // inverse color
}}}
return 0;
}
int PlotPoint(complex double z, unsigned char A[]){
unsigned int ix = (creal(z)-ZxMin)/PixelWidth;
unsigned int iy = (ZyMax - cimag(z))/PixelHeight;
unsigned int i = Give_i(ix,iy); /* index of _data array */
A[i]= 255-A[i]; // Mark point with inveres color
return 0;
}
int DrawForwardOrbit(complex double z, unsigned long long int iMax, unsigned char A[] )
{
unsigned long long int i; /* nr of point of critical orbit */
PlotBigPoint(z, A);
/* forward orbit of critical point */
for (i=1;i<iMax ; ++i)
{
z = F(z,C);
if (cabs2(z - zp1p) > 2.0) {return 1;} // escaping
PlotBigPoint(z, A);
}
return 0;
}
// ***********************************************************************************************
// ********************** edge detection usung Sobel filter ***************************************
// ***************************************************************************************************
// from Source to Destination
int ComputeBoundaries(unsigned char S[], unsigned char D[])
{
unsigned int iX,iY; /* indices of 2D virtual array (image) = integer coordinate */
unsigned int i; /* index of 1D array */
/* sobel filter */
unsigned char G, Gh, Gv;
// boundaries are in D array ( global var )
// clear D array
memset(D, iColorOfExterior, iSize*sizeof(*D)); // for heap-allocated arrays, where N is the number of elements = FillArrayWithColor(D , iColorOfExterior);
// printf(" find boundaries in S array using Sobel filter\n");
#pragma omp parallel for schedule(dynamic) private(i,iY,iX,Gv,Gh,G) shared(iyMax,ixMax)
for(iY=1;iY<iyMax-1;++iY){
for(iX=1;iX<ixMax-1;++iX){
Gv= S[Give_i(iX-1,iY+1)] + 2*S[Give_i(iX,iY+1)] + S[Give_i(iX-1,iY+1)] - S[Give_i(iX-1,iY-1)] - 2*S[Give_i(iX-1,iY)] - S[Give_i(iX+1,iY-1)];
Gh= S[Give_i(iX+1,iY+1)] + 2*S[Give_i(iX+1,iY)] + S[Give_i(iX-1,iY-1)] - S[Give_i(iX+1,iY-1)] - 2*S[Give_i(iX-1,iY)] - S[Give_i(iX-1,iY-1)];
G = sqrt(Gh*Gh + Gv*Gv);
i= Give_i(iX,iY); /* compute index of 1D array from indices of 2D array */
if (G==0) {D[i]=255;} /* background */
else {D[i]=0;} /* boundary */
}
}
return 0;
}
// copy from Source to Destination
int CopyBoundaries(unsigned char S[], unsigned char D[])
{
unsigned int iX,iY; /* indices of 2D virtual array (image) = integer coordinate */
unsigned int i; /* index of 1D array */
//printf("copy boundaries from S array to D array \n");
for(iY=1;iY<iyMax-1;++iY)
for(iX=1;iX<ixMax-1;++iX)
{i= Give_i(iX,iY); if (S[i]==0) D[i]=0;}
return 0;
}
// *******************************************************************************************
// ********************************** save A array to pgm file ****************************
// *********************************************************************************************
int
SaveArray2PGMFile (unsigned char A[], int a, int b, int c, char *comment)
{
FILE *fp;
const unsigned int MaxColorComponentValue = 255; /* color component is coded from 0 to 255 ; it is 8 bit color file */
char name[100]; /* name of file */
snprintf (name, sizeof name, "%d_%d_%d", a, b, c ); /* */
char *filename = strcat (name, ".pgm");
char long_comment[200];
sprintf (long_comment, "fc(z)=z*(1+z)*(1+z)*(C-(2C+1)*z+(3+4*C)*z*z/4) %s", comment);
// save image array to the pgm file
fp = fopen (filename, "wb"); // create new file,give it a name and open it in binary mode
fprintf (fp, "P5\n # %s\n %u %u\n %u\n", long_comment, iWidth, iHeight, MaxColorComponentValue); // write header to the file
size_t rSize = fwrite (A, sizeof(A[0]), iSize, fp); // write whole array with image data bytes to the file in one step
fclose (fp);
// info
if ( rSize == iSize)
{
printf ("File %s saved ", filename);
if (long_comment == NULL || strlen (long_comment) == 0)
printf ("\n");
else { printf (". Comment = %s \n", long_comment); }
}
else {printf("wrote %zu elements out of %llu requested\n", rSize, iSize);}
return 0;
}
int
PrintCInfo ()
{
printf ("gcc version: %d.%d.%d\n", __GNUC__, __GNUC_MINOR__, __GNUC_PATCHLEVEL__); // https://stackoverflow.com/questions/20389193/how-do-i-check-my-gcc-c-compiler-version-for-my-eclipse
// OpenMP version is displayed in the console : export OMP_DISPLAY_ENV="TRUE"
printf ("__STDC__ = %d\n", __STDC__);
printf ("__STDC_VERSION__ = %ld\n", __STDC_VERSION__);
printf ("c dialect = ");
switch (__STDC_VERSION__)
{ // the format YYYYMM
case 199409L:
printf ("C94\n");
break;
case 199901L:
printf ("C99\n");
break;
case 201112L:
printf ("C11\n");
break;
case 201710L:
printf ("C18\n");
break;
//default : /* Optional */
}
return 0;
}
int
PrintProgramInfo ()
{
// display info messages
printf ("Numerical approximation of Julia set for F(z,C) = z*(1+z)*(1+z)*(C-(2C+1)*z+(3+4*C)*z*z/4) \n");
//printf ("iPeriodParent = %d \n", iPeriodParent);
//printf ("iPeriodOfChild = %d \n", iPeriodChild);
printf ("parameter C = ( %.16f ; %.16f ) \n", creal (C), cimag (C));
printf ("Image Width = %f in world coordinate\n", ZxMax - ZxMin);
printf ("PixelWidth = %.16f \n", PixelWidth);
printf ("AR = %.16f = %f *PixelWidth\n", AR, AR / PixelWidth);
printf("pixel counters\n");
printf ("uUnknown = %llu\n", uUnknown);
printf ("uExterior = %llu\n", uExterior);
printf ("uInterior = %llu\n", uInterior);
printf ("Sum of pixels = %llu\n", uInterior+uExterior + uUnknown);
printf ("all pixels of the array = iSize = %llu\n", iSize);
// image corners in world coordinate
// center and radius
// center and zoom
// GradientRepetition
printf ("Maximal number of iterations = iterMax = %d \n", IterMax);
printf ("ratio of image = %f ; it should be 1.000 ...\n", ratio);
//
return 0;
}
int SetPlane(complex double center, double radius, double a_ratio){
ZxMin = creal(center) - radius*a_ratio;
ZxMax = creal(center) + radius*a_ratio; //0.75;
ZyMin = cimag(center) - radius; // inv
ZyMax = cimag(center) + radius; //0.7;
return 0;
}
// *****************************************************************************
//;;;;;;;;;;;;;;;;;;;;;; setup ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
// **************************************************************************************
int
setup ()
{
fprintf (stderr, "setup start\n");
/* 2D array ranges */
iWidth = iHeight* DisplayAspectRatio ;
iSize = iWidth * iHeight; // size = number of points in array
// iy
iyMax = iHeight - 1; // Indexes of array starts from 0 not 1 so the highest elements of an array is = array_name[size-1].
//ix
ixMax = iWidth - 1;
/* 1D array ranges */
// i1Dsize = i2Dsize; // 1D array with the same size as 2D array
iMax = iSize - 1; // Indexes of array starts from 0 not 1 so the highest elements of an array is = array_name[size-1].
SetPlane( center, radius, DisplayAspectRatio );
/* Pixel sizes */
PixelWidth = (ZxMax - ZxMin) / ixMax; // ixMax = (iWidth-1) step between pixels in world coordinate
PixelHeight = (ZyMax - ZyMin) / iyMax;
ratio = ((ZxMax - ZxMin) / (ZyMax - ZyMin)) / ((double) iWidth / (double) iHeight); // it should be 1.000 ...
ER = 2.0; //
ER2 = ER*ER;
AR = 18.5*PixelWidth*iWidth/2000.0 ; // adjust first number
AR2 = AR * AR;
//AR12 = AR/2.0;
/* create dynamic 1D arrays for colors ( shades of gray ) */
data = malloc (iSize * sizeof (unsigned char));
edge = malloc (iSize * sizeof (unsigned char));
if (data == NULL || edge == NULL)
{
fprintf (stderr, " Could not allocate memory");
return 1;
}
fprintf (stderr, " end of setup \n");
return 0;
} // ;;;;;;;;;;;;;;;;;;;;;;;;; end of the setup ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
int
end ()
{
fprintf (stderr, " allways free memory (deallocate ) to avoid memory leaks \n"); // https://en.wikipedia.org/wiki/C_dynamic_memory_allocation
free (data);
free(edge);
PrintProgramInfo ();
PrintCInfo ();
return 0;
}
// ********************************************************************************************************************
/* ----------------------------------------- main -------------------------------------------------------------*/
// ********************************************************************************************************************
int
main ()
{
setup ();
DrawFatouImage (data, IterMax); // first find Fatou
SaveArray2PGMFile (data, iWidth, IterMax, 0, "Fatou, name = iWidth_IterMax_n");
ComputeBoundaries(data,edge);
SaveArray2PGMFile (edge, iWidth, IterMax, 1, "Boundaries of Fatou; name = iWidth_IterMax_n");
CopyBoundaries(edge,data);
SaveArray2PGMFile (data, iWidth, IterMax, 2, "Fatou with boundaries; name = iWidth_IterMax_n");
//MarkAttractors(data);
MarkTraps(data);
SaveArray2PGMFile (data, iWidth, IterMax, 4, "Fatou with boundaries and traps; name = iWidth_IterMax_n");
DrawForwardOrbit(zc1p, 10000, data);
SaveArray2PGMFile (data, iWidth, IterMax, 5, "Fatou with boundaries and traps, critical orbit; name = iWidth_IterMax_n");
end ();
return 0;
}
text output
time ./a.out > a.txt OPENMP DISPLAY ENVIRONMENT BEGIN _OPENMP = '201511' OMP_DYNAMIC = 'FALSE' OMP_NESTED = 'FALSE' OMP_NUM_THREADS = '8' OMP_SCHEDULE = 'DYNAMIC' OMP_PROC_BIND = 'FALSE' OMP_PLACES = '' OMP_STACKSIZE = '0' OMP_WAIT_POLICY = 'PASSIVE' OMP_THREAD_LIMIT = '4294967295' OMP_MAX_ACTIVE_LEVELS = '2147483647' OMP_CANCELLATION = 'FALSE' OMP_DEFAULT_DEVICE = '0' OMP_MAX_TASK_PRIORITY = '0' OMP_DISPLAY_AFFINITY = 'FALSE' OMP_AFFINITY_FORMAT = 'level %L thread %i affinity %A' OPENMP DISPLAY ENVIRONMENT END compute Fatou image File 13000_100000_0.pgm saved . Comment = fc(z)=z*(1+z)*(1+z)*(C-(2C+1)*z+(3+4*C)*z*z/4) Fatou, name = iWidth_IterMax_n File 13000_100000_1.pgm saved . Comment = fc(z)=z*(1+z)*(1+z)*(C-(2C+1)*z+(3+4*C)*z*z/4) Boundaries of Fatou; name = iWidth_IterMax_n File 13000_100000_2.pgm saved . Comment = fc(z)=z*(1+z)*(1+z)*(C-(2C+1)*z+(3+4*C)*z*z/4) Fatou with boundaries; name = iWidth_IterMax_n File 13000_100000_4.pgm saved . Comment = fc(z)=z*(1+z)*(1+z)*(C-(2C+1)*z+(3+4*C)*z*z/4) Fatou with boundaries and traps; name = iWidth_IterMax_n File 13000_100000_5.pgm saved . Comment = fc(z)=z*(1+z)*(1+z)*(C-(2C+1)*z+(3+4*C)*z*z/4) Fatou with boundaries and traps, critical orbit; name = iWidth_IterMax_n Numerical approximation of Julia set for F(z,C) = z*(1+z)*(1+z)*(C-(2C+1)*z+(3+4*C)*z*z/4) parameter C = ( 1.0200000000000000 ; 0.0500000000000000 ) Image Width = 3.120000 in world coordinate PixelWidth = 0.0002400184629587 AR = 0.0288622201707824 = 120.250000 *PixelWidth pixel counters uUnknown = 0 uExterior = 48939153 uInterior = 18681357 Sum of pixels = 67620510 all pixels of the array = iSize = 130000000 Maximal number of iterations = iterMax = 100000 ratio of image = 1.000000 ; it should be 1.000 ... gcc version: 9.3.0 __STDC__ = 1 __STDC_VERSION__ = 201710 c dialect = C18 setup start end of setup Mark traps 9999 allways free memory (deallocate ) to avoid memory leaks real 0m9,304s user 0m55,658s sys 0m0,628s
Image Magic src code
convert 13000_100000_2.pgm -resize 2600x2000 2.png
Licensing
I, the copyright holder of this work, hereby publish it under the following license:
This file is licensed under the Creative Commons Attribution-Share Alike 4.0 International license.
- You are free:
- to share – to copy, distribute and transmit the work
- to remix – to adapt the work
- Under the following conditions:
- attribution – You must give appropriate credit, provide a link to the license, and indicate if changes were made. You may do so in any reasonable manner, but not in any way that suggests the licensor endorses you or your use.
- share alike – If you remix, transform, or build upon the material, you must distribute your contributions under the same or compatible license as the original.
References
File history
Click on a date/time to view the file as it appeared at that time.
| Date/Time | Thumbnail | Dimensions | User | Comment | |
|---|---|---|---|---|---|
| current | 19:19, 30 September 2020 | | 2,600 × 2,000 (165 KB) | Soul windsurfer | Uploaded own work with UploadWizard |
File usage
The following pages on the English Wikipedia use this file (pages on other projects are not listed):
