generating random particles in a cylinder

2 vues (au cours des 30 derniers jours)
hamed
hamed le 11 Juin 2015
Commenté : Denisse Campos Muñoz le 17 Fév 2016
I am trying to generate random particles in a cylinder corresponds to a finite volume fraction. Therefore, each volume fraction results in different number of particles. But, as volume fraction increases, say number of particles increases, the simulation time increases dramatically. For example, for 1100 particles (about volume fraction equal to 0.3) it takes just a minute to generate them in a way that they maintain within the cylinder boundaries and also do not overlap. However, if I want 1400 particles corresponds to volume fraction 0.4 it took about 24 hours and still not finished. Any suggestion is appreciated. The code is as below;
vol_frac=0.400831;
lz=0.04;
lx=lz;ly=lx;
x(1)=(2*lz-2*R)*rand(1)-lz+R;
y(1)=(2*sqrt(lz^2-x(1)^2)-2*R)*rand(1)-sqrt(lz^2-x(1)^2)+R;
z(1)=(2*lz-2*R)*rand(1)-lz+R;
%no. of particles
Npart=round(6*0.08^3*vol_frac/4/0.006^3);
%Npart=1100;
for i=2:Npart;
x(i)=(2*lz-2*R)*rand(1)-lz+R;
y(i)=(2*sqrt(lz^2-x(i)^2)-2*R)*rand(1)-sqrt(lz^2-x(i)^2)+R;
z(i)=(2*lz-2*R)*rand(1)-lz+R;
k=i-1;
while k>=1;
c=((y(k)-y(i))^2+(x(k)-x(i))^2+(z(k)-z(i))^2)^0.5;
if c<=2*R
x(i)=(2*lz-2*R)*rand(1)-lz+R;
y(i)=(2*sqrt(lz^2-x(i)^2)-2*R)*rand(1)-sqrt(lz^2-x(i)^2)+R;
z(i)=(2*lz-2*R)*rand(1)-lz+R;
k=i-1;
else
k=k-1;
end
end
end
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hamed
hamed le 14 Juin 2015
I'm still not getting appropriate answer. I think the problem is due to random number rejection by overlapping check which results in predictable random numbers. However, I have revised the previous code due to mapping like this and becomes faster;
%Initial random position of particles (Normal distribution)
vol_frac=0.400831;
%no. of particles
rng shuffle
% Npart=1100;
R=0.003;
Npart=round(6*0.08^3*vol_frac/4/0.006^3);
x=zeros(1,Npart);y=zeros(1,Npart);z=zeros(1,Npart);
lz=0.04;
lx=lz;ly=lx;
teta=2*pi*rand;
ri=(lz-R)*sqrt(rand);
x(1)=ri*cos(teta);
y(1)=ri*sin(teta);
z(1)=(2*lz-2*R)*rand-lz+R;
for i=2:Npart;
teta=2*pi*rand;
ri=(lz-R)*sqrt(rand);
x(i)=ri*cos(teta);
y(i)=ri*sin(teta);
z(i)=(2*lz-2*R)*rand-lz+R;
k=i-1;
while k>=1;
c=((y(k)-y(i))^2+(x(k)-x(i))^2+(z(k)-z(i))^2)^0.5;
if c<2*R
teta=2*pi*rand;
ri=(lz-R)*sqrt(rand);
x(i)=ri*cos(teta);
y(i)=ri*sin(teta);
z(i)=(2*lz-2*R)*rand-lz+R;
k=i-1;
else
k=k-1;
end
end
end
Denisse Campos Muñoz
Denisse Campos Muñoz le 17 Fév 2016
I used your code to generating particles in cylindrical coordinates and that these follow uniform distribution using random ('unif', ..., ...) and would like to know how to graph the particles.
How I can plot the distributed along the center of each particle?

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