# Calculate largest rectangle in a rotated rectangle

I'm trying to find the best way to calculate the biggest (in area) rectangle which can be contained inside a rotated rectangle.

Some pictures should help (I hope) in visualizing what I mean:

The width and height of the input rectangle is given and so is the angle to rotate it. The output rectangle is not rotated or skewed.

I'm going down the longwinded route which I'm not even sure if it will handle the corner cases (no pun intended). I'm certain there is an elegant solution to this. Any tips?

EDIT: The output rectangle points don't necessarily have to touch the input rectangles edges. (Thanks to Mr E)

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By "biggest rectangle", do you mean the one with the largest area? –  Sven Marnach Apr 26 '11 at 10:54
@Sven yes, thats what is meant. I'll do an edit...Thanks. –  zaf Apr 26 '11 at 10:56
+1 for the drawings :) –  George Profenza Apr 26 '11 at 11:01
Isn't this more of a math problem than a programming one? –  Jonas Elfström Apr 26 '11 at 11:13
@zaf look at the picture here: i.imgur.com/22yAQ.jpg , perhaps slightly more rotated. How can you fit such a rectangle inside this one? –  YXD Apr 26 '11 at 11:26

I just came here looking for the same answer. After shuddering at the thought of so much math involved, I thought I would resort to a semi-educated guess. Doodling a bit I came to the (intuitive and probably not entirely exact) conclusion that the largest rectangle is proportional to the outer resulting rectangle, and its two opposing corners lie at the intersection of the diagonals of the outer rectangle with the longest side of the rotated rectangle. For squares, any of the diagonals and sides would do... I guess I am happy enough with this and will now start brushing the cobwebs off my rusty trig skills (pathetic, I know).

Minor update... Managed to do some trig calculations. This is for the case when the Height of the image is larger than the Width.

Update. Got the whole thing working. Here is some js code. It is connected to a larger program, and most variables are outside the scope of the functions, and are modified directly from within the functions. I know this is not good, but I am using this in an isolated situation, where there will be no confusion with other scripts: redacted

I took the liberty of cleaning the code and extracting it to a function:

``````function getCropCoordinates(angleInRadians, imageDimensions) {
var img = imageDimensions;

var quadrant = Math.floor(ang / (Math.PI / 2)) & 3;
var sign_alpha = (quadrant & 1) === 0 ? ang : Math.PI - ang;
var alpha = (sign_alpha % Math.PI + Math.PI) % Math.PI;

var bb = {
w: img.w * Math.cos(alpha) + img.h * Math.sin(alpha),
h: img.w * Math.sin(alpha) + img.h * Math.cos(alpha)
};

var gamma = img.w < img.h ? Math.atan2(bb.w, bb.h) : Math.atan2(bb.h, bb.w);

var delta = Math.PI - alpha - gamma;

var length = img.w < img.h ? img.h : img.w;
var d = length * Math.cos(alpha);
var a = d * Math.sin(alpha) / Math.sin(delta);

var y = a * Math.cos(gamma);
var x = y * Math.tan(gamma);

return {
x: x,
y: y,
w: bb.w - 2 * x,
h: bb.h - 2 * y
};
}
``````

I encountered some problems with the `gamma`-calculation, and modified it to take into account in which direction the original box is the longest.

-- Magnus Hoff

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Nice graphics. I'll think about this idea. If you manage to produce code then please post it here! –  zaf Sep 22 '11 at 14:30
I am working on the same problem right now. Trying to build a WYSIWYG front-end for some server-based image rotation and cropping. I did some calculations too. Posting them here. As images.... I haven't coded anything yet. –  Andri Sep 22 '11 at 16:54
Done. The code needs some cleanup, but it's working fine. –  Andri Sep 23 '11 at 18:47
I ended up using this. Thank you! In the process I rewrote your code. I posted it as an edit, as I think it is better, but please feel free to revert it or edit it further :) –  Magnus Hoff Feb 25 '13 at 15:16

Trying not to break tradition putting the solution of the problem as a picture:)

Edit: Third equations is wrong. The correct one is:

3.w * cos(α) * X + w * sin(α) * Y - w * w * sin(α) * cos(α) - w * h = 0

To solve the system of linear equations you can use Cramer rule, or Gauss method.

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Good work, have removed my answer. –  YXD Apr 26 '11 at 13:41
Thank you! @Mr E. –  Mihran Hovsepyan Apr 26 '11 at 13:44
How is it possible to put P, Q, R, S to equations 1, 2, 3, and 4? Please give a sample on a substitution into one of the 4 equations. Thank you. –  Neigyl R. Noval Apr 26 '11 at 14:12
P should be puted in first equation (which is equation of line (A, B)). And because P(x1, y1) is on that line, the `x1` and `y1` should be such that the equality `w * cos(a) * x1 + w * sin(a) * y1 -w * w * sin(a) * cos(a) = 0` holds. –  Mihran Hovsepyan Apr 26 '11 at 14:20
@Mihran Hovsepyan thanks for that. I'll look into it and see if I can grok it. –  zaf Apr 28 '11 at 7:28

First, we take care of the trivial case where the angle is zero or a multiple of pi/2. Then the largest rectangle is the same as the original rectangle.

In general, the inner rectangle will have 3 points on the boundaries of the outer rectangle. If it does not, then it can be moved so that one vertex will be on the bottom, and one vertex will be on the left. You can then enlarge the inner rectangle until one of the two remaining vertices hits a boundary.

We call the sides of the outer rectangle R1 and R2. Without loss of generality, we can assume that R1 <= R2. If we call the sides of the inner rectangle H and W, then we have that

``````H cos a + W sin a <= R1
H sin a + W cos a <= R2
``````

Since we have at least 3 points on the boundaries, at least one of these inequality must actually be an equality. Let's use the first one. It is easy to see that:

``````W = (R1 - H cos a) / sin a
``````

and so the area is

``````A = H W = H (R1 - H cos a) / sin a
``````

We can take the derivative wrt. H and require it to equal 0:

``````dA/dH = ((R1 - H cos a) - H cos a) / sin a
``````

Solving for H and using the expression for W above, we find that:

``````H = R1 / (2 cos a)
W = R1 / (2 sin a)
``````

Substituting this in the second inequality becomes, after some manipulation,

``````R1 (tan a + 1/tan a) / 2 <= R2
``````

The factor on the left-hand side is always at least 1. If the inequality is satisfied, then we have the solution. If it isn't satisfied, then the solution is the one that satisfies both inequalities as equalities. In other words: it is the rectangle which touches all four sides of the outer rectangle. This is a linear system with 2 unknowns which is readily solved:

``````H = (R2 cos a - R1 sin a) / cos 2a
W = (R1 cos a - R2 sin a) / cos 2a
``````

In terms of the original coordinates, we get:

``````x1 = x4 = W sin a cos a
y1 = y2 = R2 sin a - W sin^2 a
x2 = x3 = x1 + H
y3 = y4 = y2 + W
``````
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Nice. I'll check it out. –  zaf Sep 23 '11 at 10:18
@zaf AFAIK, my answer is the only correct one. –  Jeffrey Sax Sep 26 '11 at 16:33
I'll try to find some time to check your solution. Can you see a quick way to get the xy position (one will do if there are multiple positions) of the target inner rectangle? –  zaf Sep 27 '11 at 14:07
Indeed this seems to be the only solution correctly distinguishing the two cases 1) R2 is long enough for getting the optimal solution in terms of R1 (and the optimal rectangle does not touch the fourth side) 2) the optimal rectangle touches all 4 sides. Case 1) has an interesting property: the rectangle with maximal area touches the outer rectangle in the mid-point of the shorter side. –  coproc May 24 '13 at 12:55
I tried this solution (for my question posted here: stackoverflow.com/questions/16702966/…), but was unable to reproduce your results - can you update your answer to include a complete pseudocode function listing? –  aaronsnoswell May 27 '13 at 6:32

Edit: My Mathematica answer below is wrong - I was solving a slightly different problem than what I think you are really asking.

To solve the problem you are really asking, I would use the following algorithm(s):

On the Maximum Empty Rectangle Problem

Using this algorithm, denote a finite amount of points that form the boundary of the rotated rectangle (perhaps a 100 or so, and make sure to include the corners) - these would be the set S decribed in the paper.

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For posterity's sake I have left my original post below:

The inside rectangle with the largest area will always be the rectangle where the lower mid corner of the rectangle (the corner near the alpha on your diagram) is equal to half of the width of the outer rectangle.

I kind of cheated and used Mathematica to solve the algebra for me:

From this you can see that the maximum area of the inner rectangle is equal to 1/4 width^2 * cosecant of the angle times the secant of the angle.

Now I need to figure out what is the x value of the bottom corner for this optimal condition. Using the Solve function in mathematica on my area formula, I get the following:

Which shows that the x coordinate of the bottom corner equals half of the width.

Now just to make sure, I'll going to test our answer empirically. With the results below you can see that indeed the highest area of all of my tests (definately not exhaustive but you get the point) is when the bottom corner's x value = half of the outer rectangle's width.

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i've never used Mathematica. Could you expand some more so I can understand whats happening? –  zaf Apr 26 '11 at 13:30
Jason, please consider participating in the mathematica tag. –  Mr.Wizard Apr 26 '11 at 21:06
@Mr. Recruiting ? –  belisarius Apr 27 '11 at 3:25
@belisarius sure, why not? :-) –  Mr.Wizard Apr 27 '11 at 6:44

@Andri is not working correctly for image where `width > height` as I tested. So, I fixed and optimized his code by such way (with only two trigonometric functions):

``````calculateLargestRect = function(angle, origWidth, origHeight) {
var w0, h0;
if (origWidth <= origHeight) {
w0 = origWidth;
h0 = origHeight;
}
else {
w0 = origHeight;
h0 = origWidth;
}
// Angle normalization in range [-PI..PI)
var ang = angle - Math.floor((angle + Math.PI) / (2*Math.PI)) * 2*Math.PI;
ang = Math.abs(ang);
if (ang > Math.PI / 2)
ang = Math.PI - ang;
var sina = Math.sin(ang);
var cosa = Math.cos(ang);
var sinAcosA = sina * cosa;
var w1 = w0 * cosa + h0 * sina;
var h1 = w0 * sina + h0 * cosa;
var c = h0 * sinAcosA / (2 * h0 * sinAcosA + w0);
var x = w1 * c;
var y = h1 * c;
var w, h;
if (origWidth <= origHeight) {
w = w1 - 2 * x;
h = h1 - 2 * y;
}
else {
w = h1 - 2 * y;
h = w1 - 2 * x;
}
return {
w: w,
h: h
}
}
``````

UPDATE

Also I decided to post the following function for proportional rectange calculating:

``````calculateLargestProportionalRect = function(angle, origWidth, origHeight) {
var w0, h0;
if (origWidth <= origHeight) {
w0 = origWidth;
h0 = origHeight;
}
else {
w0 = origHeight;
h0 = origWidth;
}
// Angle normalization in range [-PI..PI)
var ang = angle - Math.floor((angle + Math.PI) / (2*Math.PI)) * 2*Math.PI;
ang = Math.abs(ang);
if (ang > Math.PI / 2)
ang = Math.PI - ang;
var c = w0 / (h0 * Math.sin(ang) + w0 * Math.cos(ang));
var w, h;
if (origWidth <= origHeight) {
w = w0 * c;
h = h0 * c;
}
else {
w = h0 * c;
h = w0 * c;
}
return {
w: w,
h: h
}
}
``````
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Thanks for the fix. My answer was edited by Magnus Hoff at some point and I have not tested the new version. I know the old (ugly) version works, since I have been using it without problems for ~2 years now. –  Andri Aug 24 '13 at 15:31

sorry for not giving a derivation here, but I solved this problem in Mathematica a few days ago and came up with the following procedure, which non-Mathematica folks should be able to read. If in doubt, please consult http://reference.wolfram.com/mathematica/guide/Mathematica.html

The procedure below returns the width and height for a rectangle with maximum area that fits into another rectangle of width w and height h that has been rotated by alpha.

``````CropRotatedDimensionsForMaxArea[{w_, h_}, alpha_] :=
With[
{phi = Abs@Mod[alpha, Pi, -Pi/2]},
Which[
w == h, {w,h} Csc[phi + Pi/4]/Sqrt[2],
w > h,
If[ Cos[2 phi]^2 < 1 - (h/w)^2,
h/2 {Csc[phi], Sec[phi]},
Sec[2 phi] {w Cos[phi] - h Sin[phi], h Cos[phi] - w Sin[phi]}],
w < h,
If[ Cos[2 phi]^2 < 1 - (w/h)^2,
w/2 {Sec[phi], Csc[phi]},
Sec[2 phi] {w Cos[phi] - h Sin[phi], h Cos[phi] - w Sin[phi]}]
]
]
``````
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Thanks for the answer and welcome to stack overflow! –  zaf Feb 9 '14 at 9:33

Here is the easiest way to do this... :)

``````Step 1
//Before Rotation

int originalWidth = 640;
int originalHeight = 480;

Step 2
//After Rotation
int newWidth = 701;  //int newWidth = 654;  //int newWidth = 513;
int newHeight = 564; //int newHeight = 757; //int newHeight = 664;

Step 3
//Difference in height and width
int widthDiff ;
int heightDiff;
int ASPECT_RATIO = originalWidth/originalHeight; //Double check the Aspect Ratio

if (newHeight > newWidth) {

int ratioDiff = newHeight - newWidth;
if (newWidth < Constant.camWidth) {
widthDiff = (int) Math.floor(newWidth / ASPECT_RATIO);
heightDiff = (int) Math.floor((originalHeight - (newHeight - originalHeight)) / ASPECT_RATIO);
}
else {
widthDiff = (int) Math.floor((originalWidth - (newWidth - originalWidth) - ratioDiff) / ASPECT_RATIO);
heightDiff = originalHeight - (newHeight - originalHeight);
}

} else {
widthDiff = originalWidth - (originalWidth);
heightDiff = originalHeight - (newHeight - originalHeight);
}

Step 4
//Calculation
int targetRectanleWidth = originalWidth - widthDiff;
int targetRectanleHeight = originalHeight - heightDiff;

Step 5
int centerPointX = newWidth/2;
int centerPointY = newHeight/2;

Step 6
int x1 = centerPointX - (targetRectanleWidth / 2);
int y1 = centerPointY - (targetRectanleHeight / 2);
int x2 = centerPointX + (targetRectanleWidth / 2);
int y2 = centerPointY + (targetRectanleHeight / 2);

Step 7
x1 = (x1 < 0 ? 0 : x1);
y1 = (y1 < 0 ? 0 : y1);
``````
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