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:

  1. Arrange the (lets say 10) X samples into a matrix like X = [x(:).^2 x(:) ones(10,1)];
  2. Arrange the Y samples into a similar matrix: Y = y(:);
  3. 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 =



*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.

Problem Setup

%// 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
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);

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.

Current example:

%// Actual work
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);

estimate2 = reshape(estimate2,[xdim,ydim]);

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)

Is there an (even) faster way?

(I don't think so.)

  • doesn't svd answer something like that?
    – user2041376
    Oct 15, 2013 at 23:50
  • 4
    @Frederick why are using psuedo inv inv(X'*X)*X instead of backslash (mldivide)?
    – Shai
    Oct 21, 2013 at 15:27
  • 2
    @Frederick: Please complete your code. It seems impossible to put something for Y which makes coeff(x,y) a scalar
    – Daniel
    Oct 21, 2013 at 16:46
  • 1
    One simple things to possibly speed it up: permute the dimensions of image outside the loops (also don't call the variable image) to avoid calling squeeze. But without working code, I'm not going try further.
    – horchler
    Oct 21, 2013 at 17:38
  • 1
    You could convert your many independent linear equations into one large linear equation with a block-diagonal matrix. Such matrices, however, tend to have a low rank and may misbehave when trying to solve the inverse. I'd recommend trying the two simple optimizations that were suggested above (mldivide and permutation) first, though.
    – mbauman
    Oct 21, 2013 at 18:18

4 Answers 4


You can achieve a ~factor of 2 speed up by precomputing the transposition of X. i.e.

for x=1:size(picture,2) % second dimension b/c already transposed

    X = picture(:,x);
    XX = X';
    Y = randn(n_timepoints,1);
    %B = (X'*X)^-1*X'*Y; ;
    B = (XX*X)^-1*XX*Y; 
    est(x) = B(1);


Before: Elapsed time is 2.520944 seconds.
After: Elapsed time is 1.134081 seconds.

EDIT: Your code, as it stands in your latest edit, can be replaced by the following

xdim = 500; 
ydim = 500; 
n_timepoints = 10; % for example

% Actual work
picture = randn(xdim,ydim,n_timepoints);
picture = reshape(picture, [xdim*ydim,n_timepoints])'; % note transpose
YR = randn(n_timepoints,size(picture,2));

% (XX*X).^-1 = sum(picture.*picture).^-1;
% XX*Y = sum(picture.*YR);
est = sum(picture.*picture).^-1 .* sum(picture.*YR);

est = reshape(est,[xdim,ydim]);

Elapsed time is 0.127014 seconds.

This is an order of magnitude speed up on the latest edit, and the results are all but identical to the previous method.


Okay, so if X is a matrix, not a vector, things are a little more complicated. We basically want to precompute as much as possible outside of the for-loop to keep our costs down. We can also get a significant speed-up by computing XT*X manually - since the result will always be a symmetric matrix, we can cut a few corners to speed things up. First, the symmetric multiplication function:

function XTX = sym_mult(X) % X is a 3-d matrix

n = size(X,2);
XTX = zeros(n,n,size(X,3));
for i=1:n
    for j=i:n
        XTX(i,j,:) = sum(X(:,i,:).*X(:,j,:));
        if i~=j
            XTX(j,i,:) = XTX(i,j,:);

Now the actual computation script

xdim = 500; 
ydim = 500; 
n_timepoints = 10; % for example

Y = randn(10,xdim*ydim);
picture = randn(xdim,ydim,n_timepoints); % 500x500x10

% Actual work  
tic  % start timing

picture = reshape(picture, [xdim*ydim,n_timepoints])';

% Here we precompute the (XT*Y) calculation to speed things up later
picture_y = [sum(Y);sum(Y.*picture)]; 

% initialize
est = zeros(size(picture,2),1); 

picture = permute(picture,[1,3,2]);
XTX = cat(2,ones(n_timepoints,1,size(picture,3)),picture);
XTX = sym_mult(XTX); % precompute (XT*X) for speed

X = zeros(2,2); % preallocate for speed
XY = zeros(2,1);

for x=1:size(picture,2) % second dimension b/c already transposed

    %For some reason this is a lot faster than X = XTX(:,:,x);
    X(1,1) = XTX(1,1,x);
    X(2,1) = XTX(2,1,x);
    X(1,2) = XTX(1,2,x);
    X(2,2) = XTX(2,2,x);
    XY(1) = picture_y(1,x);
    XY(2) = picture_y(2,x);

    % Here we utilise the fact that A\B is faster than inv(A)*B
    % We also use the fact that (A*B)*C = A*(B*C) to speed things up
    B = X\XY;
    est(x) = B(1); 
est = reshape(est,[xdim,ydim]); 
toc % end timing

Before: Elapsed time is 4.56 seconds.
After: Elapsed time is 2.24 seconds.

This is a speed up of about a factor of 2. This code should be extensible to X being any dimensions you want. For instance, in the case where X = [1 x x^2], you would change picture_y to the following

picture_y = [sum(Y);sum(Y.*picture);sum(Y.*picture.^2)];

and change XTX to

XTX = cat(2,ones(n_timepoints,1,size(picture,3)),picture,picture.^2); 

You would also change a lot of 2s to 3s in the code, and add XY(3) = picture_y(3,x) to the loop. It should be fairly straight-forward, I believe.

  • Ah, I need to edit my example. This will work very well when "X" is Nx1, but generally, X is a Nx(>1) matrix.
    – Frederick
    Oct 22, 2013 at 15:35
  • Ah right. I've made an amendment to my answer with some more enhancements.
    – MrAzzaman
    Oct 24, 2013 at 3:22


I sped up your original version, since your edit 3 was actually not working (and also does something different).

So, on my PC:

Your (original) version: 8.428473 seconds.
My obfuscated one-liner given below: 0.964589 seconds.

First, for no other reason than to impress, I'll give it as I wrote it:

%%// Some example data
xdim = 500; 
ydim = 500; 
n_timepoints = 10; % for example
estimate = zeros(xdim,ydim); %// initialization with explicit size

picture = randn(xdim,ydim,n_timepoints);

%%// Your original solution
%// (slightly altered to make my version's results agree with yours)


Y = randn(n_timepoints,xdim*ydim);
ii = 1;
for x = 1:xdim
    for y = 1:ydim

        X = squeeze(picture(x,y,:)); %// or similar creation of X matrix

        B = (X'*X)^(-1)*X' * Y(:,ii);
        ii = ii+1;

        %// sometimes you keep everything and do
        %// estimate(x,y,:) = B(:);
        %// sometimes just the first element is important and you do
        estimate(x,y) = B(1);



%%// My version 


estimate2 = reshape(sparse(1:xdim*ydim*n_timepoints, ...
    builtin('_paren', ones(n_timepoints,1)*(1:xdim*ydim),:), ...
    builtin('_paren', permute(picture, [3 2 1]),:))\Y(:), ydim,xdim).';  %'


%%// Check for equality

max(abs(estimate(:)-estimate2(:)))  % (always less than ~1e-14)


First, here's the version that you should actually use:

%// Construct sparse block-diagonal matrix
%// (Type "help sparse" for more information)
N  = xdim*ydim;      %// number of columns
M  = N*n_timepoints; %// number of rows
ii = 1:N;
jj = ones(n_timepoints,1)*(1:N);
s  = permute(picture, [3 2 1]);
X  = sparse(ii,jj(:), s(:));

%// Compute ALL the estimates at once
estimates = X\Y(:);

%// You loop through the *second* dimension first, so to make everything
%// agree, we have to extract elements in the "wrong" order, and transpose:
estimate2 = reshape(estimates, ydim,xdim).';  %'

Here's an example of what picture and the corresponding matrix X looks like for xdim = ydim = n_timepoints = 2:

>> clc, picture, full(X)

picture(:,:,1) =
   -0.5643   -2.0504
   -0.1656    0.4497
picture(:,:,2) =
    0.6397    0.7782
    0.5830   -0.3138

ans =
   -0.5643         0         0         0
    0.6397         0         0         0
         0   -2.0504         0         0
         0    0.7782         0         0
         0         0   -0.1656         0
         0         0    0.5830         0
         0         0         0    0.4497
         0         0         0   -0.3138

You can see why sparse is necessary -- it's mostly zeros, but will grow large quickly. The full matrix would quickly consume all your RAM, while the sparse one will not consume much more than the original picture matrix does.

With this matrix X, the new problem

X·b = Y

now contains all the problems

X1 · b1 = Y1
X2 · b2 = Y2


b = [b1; b2; b3; ...]
Y = [Y1; Y2; Y3; ...]

so, the single command


will solve all your systems at once.

This offloads all the hard work to a set of highly specialized, compiled to machine-specific code, optimized-in-every-way algorithms, rather than the interpreted, generic, always-two-steps-away from the hardware loops in MATLAB.

It should be straightforward to convert this to a version where X is a matrix; you'll end up with something like what blkdiag does, which can also be used by mldivide in exactly the same way as above.

  • Why did you change the order of the first two dimensions when using permute? This creates an X matrix that goes across columns first, then rows, which works, of course, but is sort of against the matlab preference towards columns.
    – Frederick
    Oct 24, 2013 at 17:10
  • @Frederick to make the results agree with yours :) of course, with some minor tweaking this is easily corrected. Did you try this with X being a matrix yet? Oct 24, 2013 at 17:28
  • I'm working on it now. I'm overhauling the example because it's a mess . This all-matrix was the the kind of solution I had in mind, though.
    – Frederick
    Oct 24, 2013 at 17:46
  • I wanted to show the implementation for may case, so I've added it as part of my question rather than edit this answer.
    – Frederick
    Oct 25, 2013 at 18:43
  • As a final follow-up: In the real-world use case, this is ~3x faster (2.97s to 0.94s). Thanks again.
    – Frederick
    Nov 12, 2013 at 3:51

I had a wee play around with an idea, and I decided to stick it as a separate answer, as its a completely different approach to my other idea, and I don't actually condone what I'm about to do. I think this is the fastest approach so far:

Orignal (unoptimised): 13.507176 seconds.
Fast Cholesky-decomposition method: 0.424464 seconds

First, we've got a function to quickly do the X'*X multiplication. We can speed things up here because the result will always be symmetric.

function XX = sym_mult(X)

n = size(X,2);
XX = zeros(n,n,size(X,3));
for i=1:n
    for j=i:n
        XX(i,j,:) = sum(X(:,i,:).*X(:,j,:));
        if i~=j
            XX(j,i,:) = XX(i,j,:);

The we have a function to do LDL Cholesky decomposition of a 3D matrix (we can do this because the (X'*X) matrix will always be symmetric) and then do forward and backwards substitution to solve the LDL inversion equation

function Y = fast_chol(X,XY)

L = zeros(n,n,size(X,3));
D = zeros(n,n,size(X,3));
B = zeros(n,1,size(X,3));
Y = zeros(n,1,size(X,3));
% These loops compute the LDL decomposition of the 3D matrix
for i=1:n
    D(i,i,:) = X(i,i,:);
    L(i,i,:) = 1;
    for j=1:i-1
        L(i,j,:) = X(i,j,:);
        for k=1:(j-1)
            L(i,j,:) = L(i,j,:) - L(i,k,:).*L(j,k,:).*D(k,k,:);
        D(i,j,:) = L(i,j,:);
        L(i,j,:) = L(i,j,:)./D(j,j,:);
        if i~=j
            D(i,i,:) = D(i,i,:) - L(i,j,:).^2.*D(j,j,:);

for i=1:n
    B(i,1,:) = XY(i,:);
    for j=1:(i-1)
        B(i,1,:) = B(i,1,:)-D(i,j,:).*B(j,1,:);
    B(i,1,:) = B(i,1,:)./D(i,i,:);

for i=n:-1:1
    Y(i,1,:) = B(i,1,:);
    for j=n:-1:(i+1)
        Y(i,1,:) = Y(i,1,:)-L(j,i,:).*Y(j,1,:);

Finally, we have the main script which calls all of this

xdim = 500; 
ydim = 500; 
n_timepoints = 10; % for example

Y = randn(10,xdim*ydim);
picture = randn(xdim,ydim,n_timepoints); % 500x500x10

tic  % start timing

picture = reshape(pr, [xdim*ydim,n_timepoints])';
% Here we precompute the (XT*Y) calculation
picture_y = [sum(Y);sum(Y.*picture)];

% initialize
est2 = zeros(size(picture,2),1); 

picture = permute(picture,[1,3,2]);
% Now we calculate the X'*X matrix
XTX = cat(2,ones(n_timepoints,1,size(picture,3)),picture);
XTX = sym_mult(XTX);

% Call our fast Cholesky decomposition routine
B = fast_chol(XTX,picture_y);
est2 = B(1,:);

est2 = reshape(est2,[xdim,ydim]); 

Again, this should work equally well for a Nx3 X matrix, or however big you want.

  • +1: an interesting idea indeed! But I do have a few questions: 1) the content of est2 seems to differ from what I find, and what comes out of the OPs original version 2) why not loop over the 3rd dimension and call the built-in chol to do the decomposition? Oct 25, 2013 at 5:16
  • 1) Ah, I probably messed up somewhere, it was bound to happen. OP has significantly changed how his original code looks anyway, so I'm not sure how relevant this is anymore. 2) It's actually much faster to do it my way than to do it the way you suggest - a quick test just now suggests that it could be as much as ~40x slower to loop it using the built-in method.
    – MrAzzaman
    Oct 25, 2013 at 9:34

I use octave, thus I can't say anything about the resulting performance in Matlab, but would expect this code to be slightly faster:

est=arrayfun(@(x)( (pictureT(x,:)*picture(:,x))^-1*pictureT(x,:)*randn(n_ti

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