# Projective transformation fitting

Given set of points in 3D ( X = (x1, x2, x3), Y = (y1, y2, y3) ), how can I fit transformation from X to Y?

As far as I know this is called projective transformation.
Here is example of X and Y.

Blue and red lines in X are parallel, but they are not parallel in Y.

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What was used to create these graphs? Just curious. – ja72 Jul 20 '11 at 11:37
@ja72 python + matplotlib – qutron Jul 26 '11 at 19:41
see for example tinyurl.com/5wkhaf8 – Dr. belisarius Sep 14 '11 at 4:46
I'm offering a bounty of 500 to solve this very similar question: stackoverflow.com/questions/7414809/… – smirkingman Sep 14 '11 at 10:38

Projective transformations in 3d have an associated 4x4 matrix (modulo a constant multiplication). You can find the matrix with least square fitting.

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True, and we know, but not terribly helpful – smirkingman Sep 18 '11 at 17:34

Well. I found some useful information:

This transformation is non-linear and it is not possible to represent non-linear transformation with a matrix. There are some tricks such as using homogenous coordinates. but it doesn't make all non-linear transformations representable using matrices. However, approximating a nonlinear function by a linear function is possible.

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The transformation is projective. Projective transformations are represented with matrices defined up to a multiplicative constant. – Alexandre C. Sep 15 '11 at 21:56

So, the task is to find best fitting linear transformation, right?

There is a simple solution using linear regression.

Say the transformation matrix is named `A` and has dimensions 3x3. And say you have `N` vectors (points) in 3D before and after the transformation - so you have matrices X and Y of 3 rows and N columns. Then the transformation is:

``````Y = A X + B
``````

where B is a vector of length 3 and specifies the shift. You can rewrite the matrix multiplication using indices:

``````y[i,j] = sum(k=1..3)(a[i,k] * x[k,j])  + b[i]
``````

for i = 1..3 and j = 1 .. N. So, you have 12 unknown variables (a, b), and 3 * N equations. For N >= 4, you simply find the best solution using linear regression.

For example, in R it is very easy:

``````# input data
X = matrix(c(c(0, 0, 0), c(1, 0, 0), c(0, 1, 0), c(0, 1, 1)), nrow = 3)
Y = matrix(c(c(1, 0, 1), c(2, 0, 1), c(1, 1, 1), c(1, 1, 2)), nrow = 3)
# expected transformation: A is identity matrix, b is [1, 0, 1]
N = dim(Y)[2]

# transform data for regression
a1 = rbind(t(X), matrix(rep(0, 3*2*N), ncol = 3))
a2 = rbind(matrix(rep(0, 3*N), ncol = 3), t(X), matrix(rep(0, 3*N), ncol = 3))
a3 = rbind(matrix(rep(0, 3*2*N), ncol = 3), t(X))
b1 = rep(1:0, c(N, 2*N))
b2 = rep(c(0, 1, 0), each = N)
b3 = rep(0:1, c(2*N, N))
y = as.vector(t(Y))

# do the regression
summary(lm(y ~ 0 + a1 + a2 + a3 + b1 + b2 + b3))
``````

And the output is:

``````[...]

Coefficients:
Estimate Std. Error t value Pr(>|t|)
a11  1.000e+00         NA      NA       NA
a12 -2.220e-16         NA      NA       NA
a13 -3.612e-32         NA      NA       NA
a21  7.850e-17         NA      NA       NA
a22  1.000e+00         NA      NA       NA
a23 -1.743e-32         NA      NA       NA
a31  0.000e+00         NA      NA       NA
a32  0.000e+00         NA      NA       NA
a33  1.000e+00         NA      NA       NA
b1   1.000e+00         NA      NA       NA
b2  -7.850e-17         NA      NA       NA
b3   1.000e+00         NA      NA       NA

Residual standard error: NaN on 0 degrees of freedom
Multiple R-squared:     1,      Adjusted R-squared:   NaN
F-statistic:   NaN on 12 and 0 DF,  p-value: NA
``````

as expected.

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Not linear transformation. Projective transformation. But this should be easy to adapt (projective transformations are roughly speaking 4x4 matrices whose entries sum to one). – Alexandre C. Sep 15 '11 at 21:55
The OP's request is indeed projective, but a linear projection would satisfy me. I'm afraid I'm not familiar with R. Could you possibly provide code (using EMGU+OpenCV if necessary) that I could translate to C# or VB.Net? Thanks. – smirkingman Sep 18 '11 at 17:32
@smirkingman, just use any library for linear regression to estimate matrices A and B as parameters, as I sketched above (probably use the second equation with indices). Or, if you don't find any library for C#, you can either interface R from C#, or look at how linear regression works and write your own expressions for parameter estimates. – TMS Sep 18 '11 at 22:03