Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

I have write some code but my program is too slow. The problem is as follows:

I'll build Matrix "A" to solve Ax=b problem

I have a sphere(it may be any shape), that is showed by some point,

I have assigned a coordinate vector [x y z] for each point.

N is the number of points.

Please first load (a)

[rv,N,d0]=geometrySphere(5e-9,10);         %#  Nx3 matrix [x1 y1 z1;x2 y2 z2;... ].

%# geometrySphere is a function for replacicg the sphere with points.
 L=(301:500)*1e-9;  K=2*pi./L;                   %# 1x200 array 
 %some constants ==================
 V=N*d0^3; aeq=(3*V/(4*pi))^(1/3);
for i=1:N
    r(i)=sqrt(rv(i,1)^2+rv(i,2)^2+rv(i,3)^2);    %# r is the size of each vector 
for i=1:N
    for j=1:N
        dx(i,j)=rv(i,1)-rv(j,1); %# The x component of distance between each 2 point
d=cat(3,dx,dy,dz);  %# d is the distance between each 2 point (a 3D matrix)
nd=sqrt(dx.^2+dy.^2+dz.^2);                     %# Norm of rv vector
nx=d(:,:,1)./nd; ny=d(:,:,2)./nd; nz=d(:,:,3)./nd;
n=cat(3,nx,ny,nz);                              %# Unit vectors for points that construct my sphere

 for s=1:length(L)
    % 1x200 array  in direction of x(in Cartesian coordinate system)
    % Main Loop    =================================================
    for ii=1:N                                                  
        for jj=1:N                                              
            if ii==jj                                           
                A(:,:,p)=a(s)*eye(3);           %# 3x3 , a is a 1x200 constant array                        
                p=p+1;                          %# p is only a counter              
                *[nx(ii,jj) ny(ii,jj) nz(ii,jj)]-I)+(1/nd(ii,jj)^2-1i*K(s)/nd(ii,jj))...             
                *(3*[nx(ii,jj);ny(ii,jj);nz(ii,jj)]*[nx(ii,jj) ny(ii,jj) nz(ii,jj)]-I));             

B = reshape(permute(reshape(A,3,3*N,[]),[2 1 3]),3*N,[]).';
%# concatenation of N^2 3x3 matrixes into a 3Nx3N matrix
    for i=1:N
        E00(:,i)=[E0x(i) E0y(i) E0z(i)]';

Qmax=max(Qext); Qext=Qext/Qmax;

I don't know could I explane clear?

Do you have any suggestion? Thanks in advance for any suggestions.

geometrySphere Matrix A Where I is the 3x3 identity matrix and nij nij denotes a dyadic product. n_ij n_ij

(a) after running a function is:an 1x200 array

share|improve this question
I don't understand your notation in the equation above. n_ij n_ij cannot be a dyadic product. It amounts to element-wise squaring of the n matrix. Did you mean to write different ns, like n_x, n_y? Even then, the notation is confusing. – abcd Apr 17 '11 at 6:42
@yoda: Ok, Thanks for your reminding. – Abolfazl Apr 17 '11 at 6:43
@yada: nx,ny and nz are NxN matrix for x,y and z components of unit vectors. nn for each i & j construct a 3x3 matrix. n=cat(3,nx,ny,nz), – Abolfazl Apr 17 '11 at 7:06
I think it give no error in running- when N is 1000 or more it's really time consuming – Abolfazl Apr 17 '11 at 7:56
up vote 2 down vote accepted

The first two loops can be easily replaced by the following vector operations (I haven't tested it):


d=reshape(reshape(rv(index),npairs*ndims,2)*[1 -1]',npairs,ndims);           %'

Note that in your case, dx, dy and dz will be skew-symmetric matrices with zero diagonals and hence only N(N-1)/2 independent elements. This pairing can be achieved by combnk, which gives all possible pairs from n items. Hence, the d here is an N(N-1)/2x3 element array, whereas your d is an NxNx3 array, yet contains the same information.

Now the main loop also looks like it can be vectorized, however its too long and I don't want to spend time going through all the indices. But here are some suggestions:

  1. You can do element-wise operations in MATLAB using a . prefix before the operator. So if you have two equi-dimensional arrays/vectors, like A=[a b c] and B=[d e f] (assume real), the dot product of the two vectors is simply A.*B, which gives [ad be cf]. Similar rules for division and raising it to a power. You can read more about it here.
  2. You can do matrix multiplications using the * operator (no dot here), and the inner dimensions must match. So with the above example, the inner product is simply A*B', which gives you ad+be+cf, and the outer product (dyadic product) is A'*B, which gives you a 3x3 matrix:[ad ae af;bd be bf;cd ce cf]
share|improve this answer
Ok, I think the mail loop can be vectorized with your codes, I'm working on it. Thanks yoda! – Abolfazl Apr 18 '11 at 8:26

Your Answer


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.