Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

First, see:

http://math.stackexchange.com/questions/105180/positioning-a-widget-involving-intersection-of-line-and-a-circle

I have an algorithm that solves for the height of an object given a circle and an offset.

It sort of works but the height is always off: Here is the formula: enter image description here

and here is a sketch of what it is supposed to do: enter image description here

And here is sample output from the application: enter image description here

In the formula, offset = 10 and widthRatio is 3. This is why it is (1 / 10) because (3 * 3) + 1 = 10.

The problem, as you can see is the height of the blue rectangle is not correct. I set the bottom left offsets to be the desired offset (in this case 10) so you can see the bottom left corner is correct. The top right corner is wrong because from the top right corner, I should only have to go 10 pixels until I touch the circle.

The code I use to set the size and location is:

void DataWidgetsHandler::resize( int w, int h )
    {
        int tabSz = getProportions()->getTableSize() * getProportions()->getScale();
        int r = tabSz / 2;
        agui::Point tabCenter = agui::Point(
            w * getProportions()->getTableOffset().getX(),
            h * getProportions()->getTableOffset().getY()); 

        float widthRatio = 3.0f;
        int offset = 10;
        int height = solveHeight(offset,widthRatio,tabCenter.getX(),tabCenter.getY(),r);
        int width = height * widthRatio;

        int borderMargin = height;

        m_frame->setLocation(offset,
            h - height - offset);

        m_frame->setSize(width,height);

        m_borderLayout->setBorderMargins(0,0,borderMargin,borderMargin);


    }

I can assert that the table radius and table center location are correct.

This is my implementation of the formula:

int DataWidgetsHandler::solveHeight( int offset, float widthRatio, float h, float k, float r ) const
{

    float denom = (widthRatio * widthRatio) + 1.0f;

    float rSq = denom * r * r;

    float eq = widthRatio * offset - offset - offset + h - (widthRatio * k);
    eq *= eq;
    return  (1.0f / denom) *
        ((widthRatio * h) + k - offset - (widthRatio * (offset + offset)) - sqrt(rSq - eq) );


}

It uses the quadratic formula to find what the height should be so that the distance between the top right of the rectangle, bottom left, amd top left are = offset.

Is there something wrong with the formula or implementation? The problem is the height is never long enough.

Thanks

share|improve this question
2  
Please label your diagrams. It's not clear what any variables in your formulas are, and it's not clear geometrically what the problem is. With labels you can talk about specific measures and what's wrong. –  phkahler Feb 3 '12 at 15:17
    
I don't understand the first sentence. What do you mean by solving the height given a circle and an offset? –  Carlos Feb 3 '12 at 15:19
    
See the question I linked, it should help. –  Milo Feb 3 '12 at 15:21
    
Is <code>tabCenter</code> the center of the circle or the center of the whole space? –  Isaac Feb 3 '12 at 16:26

1 Answer 1

up vote 1 down vote accepted

Well, here's my solution, which looks to resemble your solveHeight function. There might be some arithmetic errors in the below, but the method is sound.

You can think in terms of matching the coordinates at the point of the circle across from the rectangle (P).

Let o_x,o_y be the lower left corner offset distances, w and h be the height of the rectangle, w_r be the width ratio, dx be the desired distance between the top right hand corner of the rectangle and the circle (moving horizontally), c_x and c_y the coordinates of the circle's centre, theta the angle, and r the circle radius.

Labelling it is half the work! Simply write down the coordinates of the point P:

P_x = o_x + w + dx = c_x + r cos(theta)
P_y = o_y + h = c_y + r sin(theta)

and we know w = w_r * h.

To simplify the arithmetic, let's collect some of the constant terms, and let X = o_x + dx - c_x and Y = o_y - c_y. Then we have

X + w_r * h = r cos(theta)
Y + h = r sin(theta)

Squaring and summing gives a quadratic in h:

(w_r^2 + 1) * h^2 + 2 (X*w_r + Y) h + (X^2+Y^2-r^2) == 0

If you compare this with your effective quadratic, then as long as we made different mistakes :-), you might be able to figure out what's going on.

To be explicit: we can solve this using the quadratic formula, setting

a = (w_r^2 + 1) 
b = 2 (X*w_r + Y)
c = (X^2+Y^2-r^2)
share|improve this answer
    
Where do I get the angle from? –  Milo Feb 3 '12 at 15:59
    
You don't need to get it. cos^2(theta) + sin^2(theta) == 1, so it simplifies out of the final quadratic. –  DSM Feb 3 '12 at 16:00
    
How could I put it in the form of == h, I want to solve for h (the height), thanks. –  Milo Feb 3 '12 at 16:04
    
Do you know the quadratic formula? That's all my last equation is, a quadratic. –  DSM Feb 3 '12 at 16:07
    
I know (-b +/- sqrt(b^2 - 4*a*c)) / 2*a but not how to transform your form of it into that. –  Milo Feb 3 '12 at 16:08

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.