ファイル:Golden Mean Quadratic Siegel Disc Speed.png
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概要
解説Golden Mean Quadratic Siegel Disc Speed.png |
English: Golden Mean Quadratic Siegel Disc with interior colored propotional to the average discrete velocity on the orbit = abs( z_(n+1) - z_n ) |
日付 | |
原典 | It is a copy of image[1] by Chris King made with use of his Matlab code[2]. ( note that Chris have made also Julia set (white) by modified inverse iteration ). I have only converted code to Octave and made some small changes. The core of algorithm remains unchanged. Thx to Chris for the great code and releasing it under free licence . |
作者 | Adam majewski |
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Compare with
-
Gray and detailed version
-
Boundary made with MIIM
-
Animated version
-
Orbits inside Siegel Disc
Theory
Program draws dynamic plane for discrete dynamical system based on complex quadratic polynomial[3]:
Rotation number ( internal angle) t is an irrational number = the Golden Mean :[4]
It is used to compute c on the boundary of main cardioid :[5]
Inside of filled Julia set is a Siegel Disc[6] around fixed point alpha[7]:
with multiplier
such that
Algorithm
On dynamical plane one can see :
- Exterior of filled Julia set (blue) colored by level set method,
- Interior of Julia set showing irrational flow (green) coloured by the sine of the velocity
For the points that don’t escape compute the average discrete velocity of orbit :
where :
In Octave it looks :
# octave code d=0; iter = 0; while (iter < maxiter) && (abs(z)<ER) h=z; # previous point = z_(n) z=z*z+c; # next point = z_(n+1) iter = iter+1; d=d+abs(z-h); # sum of distances along orbit end if iter < maxiter # exterior measure = iter; myflag=3; # escaping to infinity else # iter==maxiter ( inside filled julia set ) measure=20*d/iter; # average distance (d/iter) = 0.5
In Chris King Maple code this discrete velocity is measured only by sum of distances between points
Because :
- all forward orbit from interior of Julia set fall into SIegel disc
- inside Siegel disc points turn around its center ( indifferent periodic point )
so distance is a good measure into which Siegel orbit point fall
Using periodic function ( sin, cos) creates bands[8] showing dynamics inside Julia set ( siegel disc and its preimages ).
Matlab src code
% code by Chris King
% http://www.dhushara.com/DarkHeart/Viewers/source/siegel.m
function siegel();
nx = 480;
ny = 480;
ColorMset = zeros(nx,ny,3);
magc=0.65;
xmin = -1/magc;
xmax = 1/magc;
ymin = -1/magc;
ymax = 1/magc;
maxiter = 1200;
wb = waitbar(0,'Please wait...');
for iy = 1:ny
cy = ymin + iy*(ymax - ymin)/(ny - 1);
for ix= 1:nx
cx = xmin + ix*(xmax - xmin)/(nx - 1);
[k myfl] = Mlevel(cy,cx,maxiter);
if myfl==2
ColorMset(ix,iy,2) = abs(sin(5*k/10+pi/4));
else
if myfl==1
ColorMset(ix,iy,1) = abs(sin(2*k/10));
else
%ColorMset(ix,iy,2) = abs(sin(2*k/10+pi/4));
ColorMset(ix,iy,3) = abs(cos(2*k/10));
end
end
end
waitbar(iy/ny,wb)
end
close(wb);
image(ColorMset);
imwrite(ColorMset,'siegel.jpg','jpg','Quality',100);
function [potential myfl] = Mlevel(cx,cy,maxiter)
z = complex(cx,cy);
th=pi*(-1+sqrt(5));
d=exp(complex(0,th));
d=d/2-d*d/4;
%e=(1-sqrt(1-4*d))/2;
%e=0;
%a=complex(0,sqrt(3));
%a=sqrt(3);
a=4;
ang=0;
iter = 0;
while (iter < maxiter)&&(abs(z) > 0.001)&&(abs(z)<20)
h=z;
%z=d*z*z*(z-a)/(1-a*z);
z=z*z+d;
hh=abs(z-h)*(z-h);
if iter>maxiter/2
ang=ang+hh;
end
iter = iter+1;
end
if iter < maxiter
potential = iter;
if abs(z)>=20
myfl=0;
else
myfl=1;
end
else
%potential = -(ang-floor(ang));
potential=abs(ang);
myfl=2;
end
Changes / questions
1. orientation of the plane : In Matlab code is definition :
function [potential myfl] = Mlevel(cx,cy,maxiter)
but use is different :
[k myfl] = Mlevel(cy,cx,maxiter);
I have changed :
[k myfl] = Mlevel(cx,cy,maxiter); # order of arguments ColorMset = zeros(ny,nx,3); # order of arguments cy = ymax - iy*(ymax - ymin)/(ny - 1); # reverse y axis ColorMset(iy,ix,1) = abs(sin(2*k/10)) # order of arguments
Now the orientation is the same as in this image[9]
I check it with :
if(cy>0 && cx>0) ColorMset(iy,ix,2)=1.0-MyImage(iy,ix,2);
2. Output file type : Png file is better then jpg in case of raster graphic
3. Speed
Is it posible to vectorize computations like in this r code[10]?
4. Names of variables
Octave src code
# http://www.dhushara.com/DarkHeart/DarkHeart.htm
# it is Octave m-file
# converted from matlab m-file by Chris King
# http://www.dhushara.com/DarkHeart/Viewers/source/siegel.m
#
# ------------- load packages ------------------------
pkg load image;
pkg load miscellaneous; # waitbar
# --------- definitions ------------------------------
function [potential myfl] = Mlevel(zx,zy,c,maxiter)
ER=2.0; # escape radius = bailout value
z = complex(zx,zy);
ang=0;
iter = 0;
while (iter < maxiter) && (abs(z) > 0.001) && (abs(z)<ER)
h=z; # previous point = z_(n)
z=z*z+c; # next point = z_(n+1)
# for the points that don''t escape compute
# the average discrete velocity on the orbit = abs( z_(n+1) - z_n )
if iter>maxiter/2 # ???
zh=z-h;
hh=abs(zh)*zh;
ang=ang+hh;
endif;
iter = iter+1;
end
if iter < maxiter
potential = iter;
if abs(z)>=ER myfl=3; # escaping to infinity
else myfl=1; # ??? falling into Siegel disc
end
else # iter==maxite ( inside filled julia set )
potential=abs(ang);
myfl=2;
end
endfunction; # Mlevel
# ------------- const ------------------------------
# integer ( screen ) coordinate
iSide=1000
nx = iSide;
ny = iSide;
# image as a 2D matrix of 24 bit colors coded from 0.0 to 1.0
MyImage = zeros(ny,nx,3); # matrix filled with 0
# world ( float) coordinate - dynamical (Z) plane
magc=0.65;
dSide=1/magc
Zxmin = -dSide;
Zxmax = dSide;
Zymin = -dSide;
Zymax = dSide;
stepy = (Zymax - Zymin)/(ny - 1); # pixel height
stepx = (Zxmax - Zxmin)/(nx - 1); # pixel width
maxiter = 2000
# fc(z) = z*z + c
# rotation number or internal angle
t = (-1+sqrt(5))/2
th=2*pi*t; # from turns to radians
d=exp(complex(0,th)); #
c =d/2-d*d/4 # point on boundary of main cardioid
pi4=pi/4;
# --------------- main : 2 loops ---------------------
waitbar(0,'Please wait...'); # info
# scan all pixels of image and comput color
for iy = 1:ny
Zy = Zymax - iy*stepy; # invert y axis
for ix= 1:nx
Zx = Zxmin + ix*stepx; # map from screen to world coordinate
[k myfl] = Mlevel(Zx,Zy,c, maxiter);
# color
switch (myfl)
case 1 MyImage(iy,ix,1) = abs(sin(2*k/10)); # ?? Julia set in red
case 2 MyImage(iy,ix,2) = abs(sin(5*k/10 + pi4)); # irrational flow (green) by the sine of the velocity.
case 3 MyImage(iy,ix,3) = abs(cos(2*k/10)); # Exterior (blue) by level sets of escape time
endswitch;
# check plane orientation
# first quadrant should be in upper right position
# if(Zy>0 && Zx>0)
# MyImage(iy,ix,2)=1.0-MyImage(iy,ix,2);
# endif;
endfor; # for ix
waitbar(iy/ny);
endfor; # for iy
# image
image(MyImage); # display image
imwrite(MyImage,'si-test.png'); # save image to file
# this requires the ImageMagick "convert" utility.
References
- ↑ Image of Julia sets by Chris King
- ↑ Matlab m-file siegel.m by Chris King
- ↑ wikipedia : Complex quadratic polynomial
- ↑ Golden ratio at wikipedia
- ↑ wikibooks : boundary_of_main_cardioid
- ↑ siegel disc at wikibooks
- ↑ Periodic points of complex quadratic mappings at wikipedia
- ↑ wikipedia : Colour banding
- ↑ Siegel disc image
- ↑ Mandelbrot animation in R
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29 10 2011
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現在の版 | 2011年10月29日 (土) 12:22 | 1,000 × 1,000 (279キロバイト) | Soul windsurfer |
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