Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I want to write a MATLAB code for the convolution of density functions .

For random variables X (with PDF f_x)and Y(with PDF f_y), the PDF of their summation, X+Y, can be obtained by the following MATLAB code:

function p=sumX_Y(z,mean1,sigma1,mean2,sigma2)
G = @(y)f_x(mean1,sigma1,z-y).*f_y(mean2,sigma2,y);p= integral(G,-Inf,Inf);

Now for summation of three random variable X+Y+Z it should be

function p=sumX_Y_Z(z,mean1,sigma1,mean2,sigma2,mean3,sigma3)
    G = @(y)sumX_Y(z-y,mean1,sigma1,mean2,sigma2).*f_z(mean3,sigma3,y);p= integral(G,-Inf,Inf);

But it will not work since the first input of the function sumX_Y is not of type double. I would appreciate if you could help me to fix this problem.

I also want to find the PDF for sum of more than 3 random variable and I do not know how to write the algorithm. Thanks a lot!

share|improve this question

migrated from programmers.stackexchange.com Sep 21 '13 at 2:50

This question came from our site for professional programmers interested in conceptual questions about software development.

2 Answers 2

You can convert a number to a double like this:

numberAsDouble = double(number);

So either convert the number before calling sumX_Y, or force it to be converted in the function itself:

function p=sumX_Y(z,mean1,sigma1,mean2,sigma2)
  G = @(y)f_x(mean1,sigma1,double(z)-y).*f_y(mean2,sigma2,y);p= integral(G,-Inf,Inf);

You could do this for all the inputs if you like.

share|improve this answer
    
the problem is z actually –  Alex Sep 21 '13 at 23:14

One way to perform the convolution is as follows:

First define sumX_Y

function p=sumX_Y(z,mean1,sigma1,mean2,sigma2)

f_x = @(x) normpdf(x,mean1,sigma1);
f_y = @(x) normpdf(x,mean2,sigma2);


for ii=1:length(z)

    G = @(y)f_x(z(ii)-y).*f_y(y);
    p(ii)= quad8(G, ...
                 min([mean1,mean2])-3*max([sigma1,sigma2])  ,...
                 max([mean1,mean2])+3*max([sigma1,sigma2])    );
end

The loop in the function above can be vectorized using the bsxfun notation btw.

Then define sumX_Y_Z as follows:

function p=sumX_Y_Z(z,mean1,sigma1,mean2,sigma2,mean3,sigma3)

f_z = @(x) normpdf(x,mean3,sigma3);
G = @(y)sumX_Y(z-y,mean1,sigma1,mean2,sigma2).*f_z(y);

p= quad8(G,min([mean1,mean2,mean3])-3*max([sigma1,sigma2,sigma3]),...
           max([mean1,mean2,mean3])+3*max([sigma1,sigma2,sigma3]));

The whole thing can be called as follows:

mean1=1;
sigma1=0.3;
mean2=2;
sigma2=1;
mean3=0;
sigma3=1;

X = 1.4; % <-- value at which to evaluate p

p=sumX_Y(X,mean1,sigma1,mean2,sigma2)
p=sumX_Y_Z(X,mean1,sigma1,mean2,sigma2,mean3,sigma3)

with output:

p =

    0.1181


p =

    0.1494

You can modify the functions to use integral instead of 'quad8', and substitute your definition of f_z etc of course.

share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.