# Coordinates transformation

I have two 3D objects in space and i want to copy the points from one object to another. The problem is that these objects don't share a common coordinate system and i have to do coordinate transformations. I have the local transformation matrix for both objects and i have also access to the world transformation matrix. I know there's some calculations to be done using these transformation matrices but i don't know how.

How can i transform one point in the first object so that it has the same position(relative to the world coordinates) if i copy it in the other object( or its coordinate system )?

Thanks

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Well, you have to apply the conversion operator that you have. E.g., the relation between polar (r, t) and cartesian (x, y) coordinates is defined by:

``````x = rcost
y = rsint
``````
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do you know how this could be done using transformation matrices? –  Jacob Krieg Oct 23 '12 at 14:29
You'll need to perform some linear algebra - multiply the point coordinates by the transformation matrix to get the coordinates in the second system. –  icepack Oct 23 '12 at 14:37
Can you please give some details? So I have a vector of 3 floats containing my xyz coordinates relative to the source shape and 3 transformation matrixex: of the origin shape, of the target shape and of the world. How can i get the 3float vector to contain the coordinates relative to the target shape? –  Jacob Krieg Oct 24 '12 at 18:11
First of all, there is no such thing as "transformation matrix of something". Transformation matrix is from coordinates system a to coordinates system b. So let's say you want to transform `(x,y,z)` to target `(x',y',z')`. You'll need to multiply the matrix A which describes the transformation (that would be one of your matrices) by `(x,y,z)` vector. If you want to do another translation, multiply the relevant matrix by `(x',y',z')`. –  icepack Oct 24 '12 at 18:17
yes, but when you multiply a vector by a matrix, the result is a matrix. which matrix's points are the one i need? –  Jacob Krieg Oct 24 '12 at 18:33