I've found myself needing to do a least-squares (or similar matrix-based operation) for every pixel in an image. Every pixel has a set of numbers associated with it, and so it can be arranged as a 3D matrix.
(This next bit can be skipped)
Quick explanation of what I mean by least-squares estimation :
Let's say we have some quadratic system that is modeled by Y = Ax^2 + Bx + C and we're looking for those A,B,C coefficients. With a few samples (at least 3) of X and the corresponding Y, we can estimate them by:
- Arrange the (lets say 10) X samples into a matrix like
X = [x(:).^2 x(:) ones(10,1)];
- Arrange the Y samples into a similar matrix:
Y = y(:);
- Estimate the coefficients A,B,C by solving:
coeffs = (X'*X)^(-1)*X'*Y;
Try this on your own if you want:
A = 5; B = 2; C = 1; x = 1:10; y = A*x(:).^2 + B*x(:) + C + .25*randn(10,1); % added some noise here X = [x(:).^2 x(:) ones(10,1)]; Y = y(:); coeffs = (X'*X)^-1*X'*Y coeffs = 5.0040 1.9818 0.9241
START PAYING ATTENTION AGAIN IF I LOST YOU THERE
*MAJOR REWRITE*I've modified to bring it as close to the real problem that I have and still make it a minimum working example.
%// Setup xdim = 500; ydim = 500; ncoils = 8; nshots = 4; %// matrix size for each pixel is ncoils x nshots (an overdetermined system) %// each pixel has a matrix stored in the 3rd and 4rth dimensions regressor = randn(xdim,ydim, ncoils,nshots); regressand = randn(xdim, ydim,ncoils);
So my problem is that I have to do a (X'*X)^-1*X'*Y (least-squares or similar) operation for every pixel in an image. While that itself is vectorized/matrixized the only way that I have to do it for every pixel is in a for loop, like:
Original code style
%// Actual work tic estimate = zeros(xdim,ydim); for col=1:size(regressor,2) for row=1:size(regressor,1) X = squeeze(regressor(row,col,:,:)); Y = squeeze(regressand(row,col,:)); B = X\Y; % B = (X'*X)^(-1)*X'*Y; %// equivalently estimate(row,col) = B(1); end end toc Elapsed time = 27.6 seconds
EDITS in reponse to comments and other ideas
I tried some things:
1. Reshaped into a long vector and removed the double
for loop. This saved some time.
2. Removed the
squeeze (and in-line transposing) by
permute-ing the picture before hand: This save alot more time.
%// Actual work tic estimate2 = zeros(xdim*ydim,1); regressor_mod = permute(regressor,[3 4 1 2]); regressor_mod = reshape(regressor_mod,[ncoils,nshots,xdim*ydim]); regressand_mod = permute(regressand,[3 1 2]); regressand_mod = reshape(regressand_mod,[ncoils,xdim*ydim]); for ind=1:size(regressor_mod,3) % for every pixel X = regressor_mod(:,:,ind); Y = regressand_mod(:,ind); B = X\Y; estimate2(ind) = B(1); end estimate2 = reshape(estimate2,[xdim,ydim]); toc Elapsed time = 2.30 seconds (avg of 10) isequal(estimate2,estimate) == 1;
Rody Oldenhuis's way
N = xdim*ydim*ncoils; %// number of columns M = xdim*ydim*nshots; %// number of rows ii = repmat(reshape(1:N,[ncoils,xdim*ydim]),[nshots 1]); %//column indicies jj = repmat(1:M,[ncoils 1]); %//row indicies X = sparse(ii(:),jj(:),regressor_mod(:)); Y = regressand_mod(:); B = X\Y; B = reshape(B(1:nshots:end),[xdim ydim]); Elapsed time = 2.26 seconds (avg of 10) or 2.18 seconds (if you don't include the definition of N,M,ii,jj)
SO THE QUESTION IS:
Is there an (even) faster way?
(I don't think so.)