Dismiss
Announcing Stack Overflow Documentation

We started with Q&A. Technical documentation is next, and we need your help.

Whether you're a beginner or an experienced developer, you can contribute.

# Computing a matrix which transfroms a quadrangle to another quadrangle in 2D

In the figure below the goal is to compute the homography matrix H which transforms the points a1 a2 a3 a4 to their counterparts b1 b2 b3 b4. That is:

``````[b1 b2 b3 b4] = H * [a1 a2 a3 a4]
``````

What way would you suggest to be the best way to calculate H(3x3). a1...b4 are points in 2D which are represented in homogeneous coordinate systems ( that is [a1_x a1_y 1]', ...). EDIT: For these types of problems we use SVD, So i would like to see how this can be simply done in Matlab.

EDIT:

Here is how I initially tried to solve it using svd (H=Q/P) in Maltlab. Cosider the following code for the given example

``````px=[0 1 1 0];  % a square
py=[1 1 0 0];

qx=[18 18 80 80];    % a random quadrangle
qy=[-20 20 60 -60];
if (DEBUG)
fill(px,py,'r');
fill(qx,qy,'r');
end

Q=[qx;qy;ones(size(qx))];
P=[px;py;ones(size(px))];
H=Q/P;
H*P-Q
-0.0000         0         0         0         0
-20.0000   20.0000  -20.0000   20.0000    0.0000
-0.0000         0         0         0   -0.0000
``````

I am expecting the answer to be a null matrix but it is not!... and that's why I asked this question in StackOverflow. Now, we all know it is a projective transformation not obviously Euclidean. However, it is good to know if in general care calculating such matrix using only 4 points is possible.

-
This is not my area, but I believe the best you can do is a least-squares solution, as you have more constraints in your equation than you have free parameters. – Isaac Jul 30 '12 at 16:45
Thats exactly right, SVD is the solution however I am missing something somewhere in my code. – C graphics Jul 30 '12 at 17:00
What are you trying right now? By analogy to linear least squares, my first guess would be `H = B * A' * inv( A * A' )` – Isaac Jul 30 '12 at 17:09
in Matlab simply H=B/A where B=[b1 b2 b3 b4], A=[a1 a2 a3 a4] – C graphics Jul 30 '12 at 17:11
And you think there should exist a matrix that does better? I'm not sure what you're asking... – Isaac Jul 30 '12 at 17:15

Using the data you posted:

``````P = [px(:) py(:)];
Q = [qx(:) qy(:)];
``````

Compute the transformation:

``````H = Q/P;
``````

apply the transformation:

``````Q2 = H*P;
``````

Compare the results:

``````err = Q2-Q
``````

output:

``````err =
7.1054e-15   7.1054e-15
-3.5527e-15  -3.5527e-15
-1.4211e-14  -2.1316e-14
1.4211e-14   1.4211e-14
``````

which is zeros for all intents and purposes..

## EDIT:

So as you pointed out in the comments, the above method will not compute the 3x3 homography matrix. It simply solves the system of equations with as many equations as points provided:

``````H * A = B   -->   H = B*inv(A)   -->   H = B/A (mrdivide)
``````

Otherwise, MATLAB has the CP2TFORM function in the image processing toolbox. Here is an example applied to the image shown:

``````%# read illustration image
img = imcomplement(im2bw(img));

%# split into two equal-sized images
imgs{1} = img(:,fix(1:end/2));
imgs{2} = img(:,fix(end/2:end-1));

%# extract the four corner points A and B from both images
C = cell(1,2);
for i=1:2
%# some processing
I = imfill(imgs{i}, 'holes');
I = bwareaopen(imclearborder(I),200);
I = imfilter(im2double(I), fspecial('gaussian'));

%# find 4 corners
C{i} = corner(I, 4);

%# sort corners in a consistent way (counter-clockwise)
idx = convhull(C{i}(:,1), C{i}(:,2));
C{i} = C{i}(idx(1:end-1),:);
end

%# show the two images with the detected corners
figure
for i=1:2
subplot(1,2,i), imshow(imgs{i})
line(C{i}(:,1), C{i}(:,2), 'Color','r', 'Marker','*', 'LineStyle','none')
text(C{i}(:,1), C{i}(:,2), num2str((1:4)'), 'Color','r', ...
'FontSize',18, 'Horiz','left', 'Vert','bottom')
end
``````

With the corners detected, now we can obtain the spatial transformation:

``````%# two sets of points
[A,B] = deal(C{:});

%# infer projective transformation using CP2TFORM
T = cp2tform(A, B, 'projective');

%# 3x3 Homography matrix
H = T.tdata.T;
Hinv = T.tdata.Tinv;

%# align points in A into B
X = tformfwd(T, A(:,1), A(:,2));

%# show result of transformation
line(X([1:end 1],1), X([1:end 1],2), 'Color','g', 'LineWidth',2)
``````

The result:

``````>> H = T.tdata.T
H =
0.74311    -0.055998    0.0062438
0.44989      -1.0567   -0.0035331
-293.31       62.704      -1.1742

>> Hinv = T.tdata.Tinv
Hinv =
-1.924     -0.42859   -0.0089411
-2.0585      -1.2615   -0.0071501
370.68       39.695            1
``````

We can confirm the calculation ourselves:

``````%# points must be in Homogenous coordinates (x,y,w)
>> Z = [A ones(size(A,1),1)] * H;
>> Z = bsxfun(@rdivide, Z, Z(:,end))   %# divide by w
Z =
152           57            1
219          191            1
62          240            1
92          109            1
``````

which maps to the points in B:

``````%# maximum error
>> max(max( abs(Z(:,1:2)-B) ))
ans =
8.5265e-14
``````
-
Thats not what I was looking for. In your solution H is 4x4, which means if we incorporate n points, H will become nxn. We are looking for a 3x3 Homography matrix.- but Thanks anyways – C graphics Jul 31 '12 at 20:24
@Cgraphics: that's true, thanks for pointing that out. Perhaps since only 4 points are enough to solve the system, it shouldn't be a problem... Either way, I have an example using CP2TFORM function as chaohuang suggested. It will correctly infer the 3x3 Homography matrix of the projective transformation from a minimum of 4 control points. I'll post it shortly, maybe someone will find it useful – Amro Jul 31 '12 at 23:02

You can try the `cp2tform` function, which infers spatial transformation from control point pairs. Since parallel is not preserved in your case, you should set the `transformtype` to be 'projective'. More info is here

-

You can use the DLT algorithm for this purpose. There are MATLAB routines available for doing that in Peter Kovesi's homepage.

-

Combine all the coordinates into column vectors. In 2D case they are: `ax`, `ay`, `bx`, `by`;

Define:

``````A = [ax, ay];
B = [bx, by];
input = [ones(size(A, 1), 1), A];
``````

Calculate transformation matrix:

``````H = input \ B;
``````

If you need to apply it on new observations `A_new`:

``````input_new = [ones(size(A_new, 1), 1), A_new];
B_new = input_new * H;
``````

Edit: you can also calculate `H` by: `H = inv(input' * input) * input' * B;` but `\` does if safely.

-
@Amro: Sorry to hijack this thread, but I wanted Amro's opinion. If you look at my answer, I have referenced my solution to a previous question. I believe it's not technically an exact duplicate but perhaps the difference is irrelevant in SO. What do you think? – Jacob Jul 30 '12 at 20:33
@Jacob: absolutely, that's a great answer. Perhaps you should post code here adapted to this problem. (btw, there seem to be a dead link pointing to some slides). IMO these questions are similar although not exact duplicates. – Amro Jul 30 '12 at 21:17

I discussed a related problem in an answer to another SO question (includes a MATLAB solution). In the linked problem, the output quadrilateral was a rectangle, but my answer handles the general problem.

-
Thanks Jacob, You are right it is exactly same question. I was looking for Homography in fact. – C graphics Jul 30 '12 at 22:59