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I know two coordinates of two vertices in a triangle (not aligned to an axis) and I'm attempting to calculate the coordinates of the third.

          a
     B ------- C
       \      |
        \     |
C'       \    |
        c \   | b
           \  |
            \ |
             \|
              A

I know the coordinates of A and B, the lengths of a and c, and that the angle C will always be a right angle. I believe there can only be two possible solutions for the coordinates of C; the one drawn above, and one with C reflected about the line c, approximately at C'. I'd like to calculate both positions.

EDIT:

The source of the triangle is from this diagram.

I know the apex A, the centre of the circle B, the radius of the circle (a) and, from Pythag with (B - A), I know the length of c. I'm trying to find the points at which a line from the apex are at a tangent to each side of the circle, C and C'.

This appears to be an answer to my problem; can anyone elaborate on 'Given two sides of a right triangle, it's easy to find the length and direction of the third side.'.

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Is it always going to be a right-angle triangle? –  U2744 SNOWFLAKE Feb 9 '12 at 1:18
    
@minitech I would guess so, or else this question wouldn't make much sense. –  EboMike Feb 9 '12 at 1:20
2  
Do you know about math.stackexchange.com? –  madth3 Feb 9 '12 at 1:20
    
@minitech Yes, angle C will always be a right angle. –  user1198585 Feb 9 '12 at 13:42

3 Answers 3

I know the coordinates of A and B, and the lengths of a and c. From this, I believe there can only be two possible solutions for the coordinates of C

This is not true. There are an infinite number of choices for the position of C, as you don't know the length of b.

For example:

C
| 
| 
| 
| 
| 
B
\      
 \     
  \    
c  \   
    \  
     \ 
      \
       A

If you connect C to A, you still maintain those known lengths....

In order for this to be true, you would also need to know one of the angles (such as that it's a right triangle), or the length of b.

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C will always be a right angle. Sorry, I forgot to mention that. –  user1198585 Feb 9 '12 at 13:41

If you know it's going to be a right triangle, then you know the x and y values will be taken from the other two points.

Point coordsForCompletingTriangleTop(Point a, Point b) {
    return new Point(a.x,b,y);
}

Point coordsForCompletingTriangleBottom(Point a, Point b) {
    return new Point(b.x,a,y);
}

If cannot be guaranteed that it will be a right triangle, then you do need more information. The length of B, the length of C, or the angle of BCA would be required.

share|improve this answer
    
The triangle isn't (necessarily) aligned to the axis; your answer doesn't take into account rotation? –  Rezzie Feb 9 '12 at 1:27
    
You have to assume axis aligned otherwise there isn't a unique result –  Matt Esch Feb 9 '12 at 13:54
    
As I said in the original post, I'm not looking for a unique solution; I'm looking for both solutions. I need both possible coordinates of C. –  user1198585 Feb 9 '12 at 23:49
    
@user mine will give you that if you can assume that the triangle you want is aligned with the axis. That is to say that AC is parallel to the Y axis and AB is parallel to the X axis. What Rezzie is saying is that without that assumption, it might be rotated around, and the coordinates of C could be at an infinite number of different places. –  corsiKa Feb 10 '12 at 0:21
    
@user also keep in mind that mine will provide you with a 0 area triangle for any points provided that form a line parallel to either axis. –  corsiKa Feb 10 '12 at 0:22

If you assume a and b are the opposite corners of a rectangle

a = (xa, ya)
b = (xb, yb)

then the top right rectangle point is c1 = (max(xa,xb), max(ya,yb)) and the bottom left rectangle point is c2 = (min(xa,xb), min(ya,yb))

Assuming that xa != xb and ya != yb

                    (xa, ya) A              C1 (max(xa, xb), max(ya, yb))
                               o----------o
                               |\         |
                               | \        |
                               |  \       |
                               |   \      |
                               |    \     |
                               |     \    |
                               |      \   |
                               |       \  |
                               |        \ |
                               o----------o
(min(xa, xb), min(ya, yb)) C2               B (xb, yb)

If your diagonal is going the other way (to test this see if xa > xb) you need to swap min for max on the x

(min(xa, xb), max(ya, yb))  C3              A'
                               o----------o
                               |         /|
                               |        / |
                               |       /  |
                               |      /   |
                               |     /    |
                               |    /     |
                               |   /      |
                               |  /       |
                               | /        |
                               o----------o
                           B'               C4 (max(xa, xb), min(ya, yb))

And if you're interested, the full set of solutions actually lies on the circle:

Set of solutions

To compute this, suppose we have two points A = (xa, ya) and B = (xb, yb). Then the center point of this circle is c = (0.5 (xa + xb), 0.5 (ya + yb)) - just the midpoint of the A and B. The radius of the circle is r = sqrt( (xb - xa)^2 + (yb - ya)^2) / 2 - using pythagoras' theorem to get the length of the line and halving it. Then any point on the circle can be defined by p = c + (rcos(u), rsin (u)) for some angle u. There are 2 angles which give you the points p = A and p = B so these values of u are not good solutions. You can write out the equation and solve it for these 2 points to give you the values of u which you cannot use.

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The length of (a,c) is fixed, there are only two solutions, see the image attached to question. –  Viesturs Oct 15 '13 at 7:08
    
The question actually changed after a number of comments were made. The original question assumed there was 1 line joining 2 points. and the second and third line were unknown. If 2 sides of a right angle triangle are known, trivial pythagoras solves the problem. –  Matt Esch Oct 15 '13 at 13:14

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