# Linear equations with multidimensional matrices [Modified]

There is a system of 3 linear equations composing of matrices which are represented by RGB image. Say

``````A = A1*x1 + A2*x2 + A3*x3    ......(Eq 1)
B=  A1*x4 + A2*x5 + A3*x6   ........(Eq 2)
C=  A1*x7 + A2*x8 + A3*x9   ........(Eq 3)
``````

each are of equal dimension say 3D. I performed the following

``````A11=rgb2gray(A1);
x11=rgb2gray(x1);
A11 =double(A1) ; x11 = double(x11); b = A1*x1;

opts.UT = true; opts.TRANSA = false;
y1 = linsolve(x1,b,opts);
imshow(y1);
``````

% The objective is to obtain A1,A2,A3 On doing this, following issues have surfaced: 1. Error The output y1 is not the same as A1, which should have been. Why is it so? Please help

-

The R,G and B spaces are orthogonal. So you can solve each of those sets independently. The problem here is that `mtimes`, which is your matrix multiplication operator, doesn't accept 3D inputs.

To solve this, you can loop through each of R, G and B and use linsolve for each of the resulting 2D matrices. Normally, I wouldn't recommend loops for anything in MATLAB, but here, there won't be any discernable overhead as there are only 3 iterations in the loop.

Your answer will not be any different from what it would be if you were to solve them all in one go (if that were possible), because the three spaces are independent.

EDIT

The way you've written your equations, the `xi`'s form the coefficient matrix and `Ai`'s are the unknowns. The system of equations can be written compactly as `XY=Z`, where `X` is a 3D matrix composed of the coefficients, `xi` for each color space,`RGB`; `Y` is a 2D matrix, with a vector `[A1, A2, A3]'` in each color space, and `Z` is also a 2D matrix with vectors `[A, B, C]'` in each color space.

Assuming that the colorspace is the last dimension, you can try

``````[xPixels,yPixels,colorSpace]=size(X);
Y=zeros(yPixels,colorspace);
opts.UT=true; opts.TRANSA=false;

for i=1:colorspace
Y(:,i)=linsolve(X(:,:,i),Z(:,i),opts);
end
``````

You'll have to setup the matrices `X`, `Y` and `Z` according to your problem. It is helpful to keep the looped dimension (in this case, `colorspace`) as the outermost dimension, as otherwise, you'll have to use `squeeze` to remove the singleton dimensions.

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@R.M: It will be highly appreciated if you kindly illustrate with the modified code. Will it be possible if i do something with immultiply? –  gavishna Mar 15 '11 at 16:17
@gavishna: I've edited my post to illustrate my point. –  git rm Mar 15 '11 at 17:28
like I said before, you cannot use matrix multiplication when you have a 3D matrix. I don't understand what you're trying to do here. Are you trying to do the forward problem or the inverse problem? If you know the matrix `Y`, then why are you using `linsolve`? If it is matrix `Z` that you need, you'll still have to loop it through to do the multiplication. –  git rm Mar 15 '11 at 17:59
yes, looping won't be necessary for a grayscale image as it's 2D. The problem with the original code is that the order of the inputs to `linsolve` are not correct. To solve the inverse problem using `linsolve`, the command is `linsolve(X,Z,opts)`, whereas your code did `linsolve(Z,X,opts)`. –  git rm Mar 15 '11 at 18:16
@gavishna: The result need not always be equal. If your matrix, `X` is not full rank, i.e., the null space of the matrix is non-empty, the inverse problem will not always give you back the original `A1`. Do you get a warning saying "Matrix is close to singular or badly scaled"? What is the output of `isempty(null(X))` and `cond(X)`? –  git rm Mar 15 '11 at 18:57