# Find all possible combinations to a sum in matlab

I'm trying to find all possible combination of sums that equal a certain matrix. Let's say I have:

``````a = [1 0 0; 0 1 0 ; 0 0 1];
b = [5 0 0; 0 5 0 ; 0 0 5];
``````

I start out with matrix `a` and want to produce matrix `b` by using matrix additions of `r1` and `r2`, e.g:

``````r1 = [1 0 0; 0 1 0 ; 0 0 1];
r2 = [2 0 0; 0 2 0 ; 0 0 2];
``````

I would want it to display the matrix, the addition, and the resulting matrix for all combination, I mean: 4r1 (1+1+1+1+1), 1r1+1r2+1r1 (1+1+2+1), 1r2+1r1+1r1 (1+2+1+1), and 2r2 (1+2+2).

This is what I got so far but I can't get it to go through all the combinations:

``````function v = test_r2(a, b)
if isequal(a,b)==1
v = [];
disp('same')
return
end
v= test_r3(a,b);
end

function v = test_r3(a, b)`
r1 = [1 0 0; 0 1 0 ; 0 0 1];
r2 = [2 0 0; 0 2 0 ; 0 0 2];

r=[{r1} {r2}];

if isequal(a,b)==1
v = b;
else % recursive call

for k = 1:numel(r)
for i = nchoosek(1:numel(r),k)'
r_matrix = r{1,i};
if(isequal(a + r_matrix,b) ==1)
disp([a(:)', r_matrix(:)'])
end
end
end
``````

Basically I want it to go through the cell array and find all possible combinations of those additions that will allow me to get from matrix `a` to matrix `b`. Any help?

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Assuming you have `n` vectors that are needed at most a factor `k` and `k*n!` is not really a big number (upto k=5 and n=10 for example or k =1000 and n=7) you could just make a few nested for loops and store the result in a huge matrix. –  Dennis Jaheruddin May 7 '13 at 8:34
Is it guaranteed that all matrices are multiples of the unit matrix? –  Eitan T May 7 '13 at 9:27
DennisJaheruddin - If possible I would like it to not store all the results in a huge matrix. I would like for the matrix sizes (a and b) to be able to expand much larger than the current 3x3 currently Eitan T - No, it is possible for matrices to be different. For example, r1 could be [0 1 3; 2 1 0; 0 0 1] –  user2356473 May 7 '13 at 14:27
any help would be much appreciated! –  user2356473 May 9 '13 at 2:24

Basically you're looking to solve the following system for x1 and x2:

x1r1 + x2r2 = b - a

In MATLAB you can do this by following these instructions from the official documentation:

``````y = reshape(b - a, [], 1);
R = [r1(:), r2(:)];
x0 = R \ y;                     %// Basic solution
Z = null(R, 'r');               %// Null space of R
``````

Any solution of the form: `x = x0 + Z * p` (for any arbitrary vector `p`) should satisfy: `y = R * x`. Note that this might give you tiny errors because of floating point operations, so consider setting a tolerance threshold and rounding them:

``````idx = (x0 - round(x0) < 100 * eps);
x0(idx) = round(x0(idx));
``````

Now let's find all possible positive integer combinations of the form `x0 + Z * p`:

``````if isempty(Z)                   %// Only one solution exists
X = x0;
else
N = max([ceil(x0); Z(:)]);  %// Set a search range
U = cell(size(Z, 2), 1);
[U{:}] = ndgrid(-N:N);
U = cellfun(@(x)x(:), U, 'UniformOutput', false);
P = [U{:}];                 %// All possible values for p within search range
X = bsxfun(@plus, x0(:).', P * Z.');
X = unique(X(all(X >= 0, 2), :), 'rows');
end

%// Keep only the positive combinations
X = unique(X(all(X >= 0, 2), :), 'rows');
``````

### Example

Let's set the initial conditions first:

``````a = eye(3);
b = 5 * eye(3);
r1 = eye(3);
r2 = 2 * eye(3);
``````

After running the first part of the code, we should get:

``````x0 =
0
2

Z =
-2
1
``````

The second part of the code should produce all possible positive integer combinations:

``````X =
0     2
2     1
4     0
``````

which correspond to the sums: 0r1 + 2r2, 2r1 + 1r2 and 4r1 + 0r2, respectively.

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