# Affine transformation matrix offset

This has been killing me the last few days. Not even kidding, but I've been really stressing over this trying to solve it.

I am currently trying to use affine transformation matrices to create an isometric projection in HTML5. I receive a tile which is a square that is rotated 45 degrees (essentially a square diamond on a square canvas). I then scale one of the axis' depending on if the there is a delta in the x or y direction. I then skew the axis by a factor to fit. Then, I negate the initial rotation by rotating it back by -45 degrees.

Currently, my affine matrix is:

``````      // note: the difference in z is about 10 in this example,
//       so, xDiff is usually 40
var xDiff  = 4 * (center.z   - map[x+1][y].land.z);
var yDiff  = 4 * (center.z   - map[x][y+1].land.z);

var matrix = multiplyAll(
// Rotation
[COS45,  SIN45,
-SIN45, COS45],

// Scale in each respective axis
[(44+yDiff)/44, 0,
0, (44+xDiff)/44],

// Skew each axis
[1,  -yDiff/(44+yDiff),
-xDiff/(44+xDiff), 1],

// Negate the rotation
[NCOS45, NSIN45,
-NSIN45, NCOS45]
);
``````

Then I draw it using:

``````      // the map has its own x & y values which directions are determined by the red x & y arrows in the picture
// pX & pY are the point relative to the canvas origin
var pX = x * 22 - y * 22 + 22;
var pY = y * 22 + x * 22 - 22 - (center.z * 4);
context.setTransform(matrix[0], matrix[1],
matrix[2], matrix[3],

300, 100);

//m_Context.drawImage(image, pX, pY);
drawDiamond(pX, pY, true); // draws a 44x44 diamond
``````

As you can see, the transformed matrices are being drawn with respect to the transformed x-axis (I think the "new" x-axis has a slope of yDiff/44). I'm not sure how to draw the shapes so that the transformed result will be in the correct position. Using `pY = x * 22 - (yDiff/10);` seems to get the point closer, but I pretty much guessed it by plugging in random numbers.

tl;dr:

• I performed a transformation
• I have a coordinate where a tile should be (if it wasn't transformed)
• How to I calculate the offset required so that a transformed tile's coordinate is the same as where it should be if it was not transformed?

PS: The weird diamonds on the bottom can be ignored for now since they can correctly be created ONCE I find out how to calculate the offsets.

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I don't understand what you need. Mostly you have linear transforms which have no offsets. To locate positions in the transformed coordinate system, can't you use the nice grid you already have? –  luser droog Feb 16 '13 at 8:54
@luserdroog The grid is created by just using tiles that aren't transformed, and so you can use a nice equation to find the location. –  Ralph Wiggum Feb 16 '13 at 9:09
+1 for cool graphics –  QED Feb 16 '13 at 9:14
Not sure if this helps, but the offsets in the affine transform (300, 100 here) bypass the scaling/skewing part. Remember, `x'=ax+by+e`, `y'=cx+dy+f`. So, `e` and `f` aren't scaled. –  luser droog Feb 16 '13 at 9:47
@luserdroog Oh man, for some reason, that never crossed my mind. So, I used (pX + 300, pY + 100) as the offset and then drew the image/diamond at (0, 0) and it worked fine. If you put that in an answer, I'll gladly accept it. –  Ralph Wiggum Feb 16 '13 at 18:14

An affine transformation matrix ([a b c d e f]) expresses the two equations

``````x' = ax + by + e
y' = cx + dy + f
``````

So, you can use the offsets e and f to bypass the scaling and skewing parts (the 4x4 linear transform embedded in the 2x3 or 3x3 matrix).

This is used a lot in postscript programming, where the coordinates used for drawing an object are relative to a local origin. If you're concatenating matrices, do the translation before scaling and skewing and the e and f values will remain unmolested.

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I have to wait 9 hours before I give you your bounty :( –  Ralph Wiggum Feb 16 '13 at 18:44
No problem. Glad I could help. –  luser droog Feb 16 '13 at 18:53