# Stochastic sample using randsample?

I'd like to make a stochastic step simulation for P and I with `randsample` like this simple one below.

``````P=zeros(1,5); I=zeros(1,5)
``````

%easy way

``````for i=1:5
X=rand; dt=0.01;

a=randi(50,1);
b=randi(50,1);
c=randi(50,1);
d=randi(50,1);

if X<=a*dt,
P(i+1)=P(i+1)+1;
elseif X>a*dt && X<=(a+b)*dt
P(i+1)=P(i)-1;
elseif X>(a+b)*dt && X<=(a+b+c)*dt
I(i+1)=I(i)-1;
elseif X>(a+b+c)*dt && X<=(a+b+c+d)*dt
I(i+1)=I(i)+1;
else  %do nothing
P(i+1)=P(i);
I(i+1)=P(i);
end
``````

%Using `randsample`

``````    Pvec=[a b c d (some value for doing nothing)]*dt;
Pvec=Pvec./sum(Pvec);
s=randsample(1:5,1,'true',Pvec);
``````

This isn't correct. How would you do it efficiently?

This is what I'm trying to do, but I don't think it's quite right...

UPDATE with competing populations I and P code Based this set of equations.

``````theta_P=0.15;delta_P=0.01;alpha_I=0.4;gamma_I=0.01;delta_I=0.005;lambda_I=0.05;
m=100;   % # runs
time=10; % # Total time of simulation
dt=0.01; % # Time step
D=6000; T=10/dt;

P=zeros(m,time/dt); I=zeros(m,time/dt);

for i=1:m
for j=1:time/dt
arrivalI=alpha_I+P(i,j)*lambda_I;
lossI=I(i,j)*gamma_I+P(i,j)*I(i,j)*delta_I;

if j<=T
alpha_P=D/T;
else
alpha_P=0;
end

arrivalP=alpha_P+P(i,j)*theta_P;
lossP=P(i,j)*I(i,j)*delta_P;

X=rand;

Pvec=[arrivalI lossI arrivalP lossP]*dt;%
Pvec=Pvec./sum(Pvec);

s=randsample(1:4,1,'true',Pvec);

if s==1
I(i,j+1)=I(i,j)+1;%;
P(i,j+1)=P(i,j);
elseif s==2
I(i,j+1)=I(i,j)-1;%
P(i,j+1)=P(i,j);
elseif s==3

P(i,j+1)=P(i,j)+1;%
I(i,j+1)=I(i,j);
elseif s==4

P(i,j+1)=P(i,j)-1;%;
I(i,j+1)=I(i,j);
else

P(i,j+1)=P(i,j);  %check
I(i,j+1)=I(i,j);
end

end

subplot(2,2,1:2)
%
if P(i,j)>5
loglog(abs(P(i,:)),'-r')
%
else
loglog(abs(P(i,:)),'-b')
%
end
hold on
axis([1 1e3 1 1e4])
end
``````
-
In your statement `if X<=a*dt`, `a` is an array. Is that intentional? –  Jonas Feb 5 '12 at 5:14
@Jonas No you're right, it's actually only supposed to be a single value evaluated at every iteration. –  HCAI Feb 5 '12 at 8:22

I don't think you can replicate your first code block "the easy way" with a call to `randsample`.
The first code block generates `P` and `I` recursively.
Whilst, randsample generates samples with or without replacement of the population: `1:5` in this case.